!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog to prevent smoking and/or burning, etc. C3E9.pdf 3.3.2 This catalog has only typical specifications. Therefore, you are requested to approve our product specifications or to transact the approval sheet for product specificaions before ordering. OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Murata EMC Solutions : http://www.murata.com/emc/ EMI SUPPESSION FILTES Murata Manufacturing Co., Ltd. Cat.No.C3E9
!Note C3E9.pdf 3.3.2 CONTENTS EMIFILr, EMIGUADr, "EMIFIL" and "EMIGUAD" in this catalog are the trademarks of Murata Manufacturing Co., Ltd. Selection Guide of EMI Filters 2 Products Guide / Effective Frequency ange 3 Outlines of EMI Suppression Filter (EMIFILr) for DC Line 6 Chip Ferrite Beads Part Numbering / Impedance Map / BLM Series Line Up 2 BLM3A/5A/8A/2A/3A/4A 8 For GHz ange Noise Suppression BLM8H/8E 53 BLM5B/8B/2B/3B 27 Array Type BLA2AA/2AB/3A/3B 6 BLM8/2 4 BLM8P/2P/3P/4P 45 2 Chip EMIFILr Part Numbering 66 Capacitor Type NFM8C/2C/3DC/4C 7 LC Combined Monolithic Type NFL8ST/8SP/2SP 8 Capacitor Array NFA3C 74 LC Combined Winding Type NFW3S 84 C Combined Type NF2G 75 LC Combined Type for Large Current NFE3P/6P/6H 86 C Combined Array Type NFA3G 79 For Large Current NFM8P/2P/3DP/4P 89 2 3 Chip EMIGUADr (EMIFILr with Varistor Function) Part Numbering 93 VFM4 94 3 4 Chip Common Mode Choke Coils Part Numbering 96 Film Type DLPS/DLP3S 97 Winding Type DLW2S/DLW2H/DLW3S Film Type Array DLP3D 99 Winding Type for Large Current DLW5AH/DLW5BS 4 Monolithic Type DLM2HG 4 5 6 Lead Type EMI Suppression Filters (EMIFILr) Ferrite Beads Inductors Part Numbering Block Type EMIFILr BL/BL2/BL3 5 BN 25 Disc Type EMIFILr Part Numbering Common Mode Choke Coils Part Numbering DSp6/Broad Band DSp9N/Heavyduty Type DSp9H 9 PLT9H 27 EMIGUADr (EMIFILr with Varistor Function) Part Numbering VF3V/VFS6V/VFS9V 7 Microwave Absorbers Part Numbering 29 EA/EA2/EA2 3 5 6!Caution / Notice 32 Soldering and Mounting 34 Packaging 43 Chip EMI Suppression Filter Design Kits 47 Outlines of Major Noise egulation Standards 52 Noise Suppression Principles by DC EMIFILr 57 Murata EMI Filter Selection Simulator 6 ecycled Paper
!Note C3E9.pdf 3.3.2 Selection Guide of EMI Filters Start Type of Circuit Headphone Line Common Mode Choke Coils 8 DC Power Line General Signal Line High Speed Signal Line DLM2HG 6Ω Ground Condition Ground Condition Signal Freq. and Noise Poor Good Poor Good Separate Mixed Chip Ferrite Beads 3terminal Capacitors Chip Ferrite Beads 3terminal Capacitors Chip Ferrite Beads 3terminal Capacitors Common Mode Choke Coils Capacitor Type Capacitor Type Combined LC T Filter 63 63 2 63 42 63 54 BLM8P.5 3A NFM8P 2A BLM3A 2Ω NFM8C 22 22pF BLM5B 5 Ω NFL8ST 5MHz DLPS 9 2Ω 85 85 42 85 63 Combined LC Filter 26 63 BLM2P.5 6A 26 NFM2P 2 4A 86 BLM5A Ω 63 NFM2C 22 22pF 25 BLM8B 5 25Ω 63 NFL8SP 5 5MHz DLP3S 2 55Ω 85 85 BLM3P.5 6A 86 NFM4P 2A Combined LC T Filter BLM8A/ 2 Ω 63 NFM3DC 22 22pF Capacitor Array BLM8HD/HB 2 Ω 85 NFL2S 2 5MHz DLW2S 67 37Ω 85 26 26 26 BLM4P 6A NFE3P 6A BLM8HG/HK/EG Ω 85 NFA3C 22 22pF BLM2B 5 27Ω Arrays NFW3S 5MHz DLW2H 67 8Ω 26 276 Combined LC T Filter 84 Combined C Filter NFE6P 2A Common Mode Choke Coils 22/24 DLW5BS(AH).2 5A 9 4Ω BLM2A/ 2 Ω Arrays 84 BLA2AA 2 Ω 26 26 NFE3P 22 22pF 276 NFE6P 33 47pF BLA2AB Ω 26 BLA3B 2 Ω 85 NF2G 22 Ω pf Combined C Array 26 NFA3G 6.8 Ω pf DLW3S 9 22Ω 22/24 DLW5BS(AH) 9 4Ω Arrays 26 BLA3A 3 Ω DLP3D 9 44Ω Dimensions in inches High Current EMI Filters Standard EMI Filters EMI Filters for High Speed Signal Lines Impedance is typical value at MHz. 2
!Note C3E9.pdf 3.3.2 Products Guide/Effective Frequency ange Product Guide Inductor Type Type For Digital Interfaces Series BLM8 Dimensions Effective Frequency ange (mm) EIA Code khz khz MHz MHzMHz GHz GHz.6.8 63 BLM2 2..25 85 Standard BLM3A.6.3 2 BLM5A..5 42 BLM8A.6.8 63 BLM2A 2..25 85 BLM3A 3.2.6 26 BLM4A 4.5.6 86 BLA2AA (4 circuits array) 2.. 84 BLA3A (4 circuits array) 3.2.6 26 For High Speed Signals BLM5B..5 42 BLM8B.6.8 63 BLM2B 2..25 85 BLM3B 3.2.6 26 BLA2AB (4 circuits array) 2.. 84 BLA3B (4 circuits array) 3.2.6 26 For High Current BLM8P.6.8 63 BLM2P 2..25 85 BLM3P 3.2.6 26 BLM4P 4.5.6 86 For GHz ange Noise Suppression BLM8HG.6.8 63 BLM8HB.6.8 63 BLM8HD.6.8 63 BLM8HK.6.8 63 BLM8EG.6.8 63 Continued on the following page. 3
!Note C3E9.pdf 3.3.2 Products Guide/Effective Frequency ange Continued from the preceding page. Type Series Dimensions Effective Frequency ange (mm) EIA Code khz khz MHz MHzMHz GHz GHz Capacitor Type Standard Type NFM8C.6.8 63 NFM2C 2..25 85 NFM3DC 3.2.25 25 NFM4C 4.5.6 86 NFA3C (4 circuits array) 3.2.6 26 For Signal Lines NFL8ST.6.8 63 NFL8SP.6.8 63 NFL2S 2..25 85 NF2G 2..25 85 NFA3G (4 circuits array) 3.2.6 26 NFW3S 3.2.6 26 For High Current NFM8P.6.8 63 NFM2P 2..25 85 NFM3DP 3.2.25 25 NFM4P 4.5.6 86 T Filter for High Current NFE3P 3.2.6 26 NFE6P(H) 6.8.6 276 With Varistor Function VFM4 4.5.6 86 Common Mode Choke Coils DLPS.25. 54 DLP3S 3.2.6 26 DLP3D 3.2.6 26 DLM2HG 2.5 2. 8 DLW2S 2..2 85 DLW2H 2..2 85 DLW3S 3.2.6 26 DLW5BS (DLW5AH) 5. 5. (3.6) 22 (24) Continued on the following page. 4
!Note C3E9.pdf 3.3.2 Products Guide/Effective Frequency ange Continued from the preceding page. Disc EMIFIL Type Series Dimensions Effective Frequency ange (mm) EIA Code khz khz MHz MHzMHz GHz GHz BL/2/3 DSN6/9(H) DSS6/9(H) DST9(H) EMIGUAD (EMI Filters with varistor functions) VF3V VFS6V/9V Block EMIFIL BN Common Mode Choke Coils PLT9H EMC Absorber EA/2/2 5
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line ochip Ferrite Bead oferrite Bead Inductor Chip Ferrite Bead...P.8 65 Ferrite Bead Inductor...P.6 8 BLM3 BLM5 BLM8 BLA2A BL BL2N3J2B BL2N23J2B BLM2 BLM3 BLM4 BLA3 BL2N BL2N2M2B BL3N2MB " Chip Ferrite Beads are effective for frequencies ranging from a few MHz to a few GHz. Chip Ferrite Beads are widely used as a low noise countermeasure, as well as a universal noise suppression component. " Chip Ferrite Beads produce a micro inductance in the low frequency range. At high frequencies, however, the resistive component of the inductor produces the primary impedance. When inserted in series in the noise producing circuit, the resistive impedance of the inductor prevents noise propagation. [Equivalent Circuit] (f) [ImpedanceFrequency Characteristics (typical)] 8 Impedance [Ω] 6 4 2 Frequency [MHz] : eal Part (esistive Portion) : Imaginary Part (Inductive Portion) 6
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line ochip EMIFILr ottype Chip EMIFILr odisk Type EMIFILr Chip EMIFILr...P.7 73 P.74 P.89 92 Ttype Chip EMIFILr...P.86 88 NFM8P NFM2C NFM2P NFE3P NFE6P/H NFM3DC NFA3C Disk Type EMIFILr...P. 6 DS6 DS9 DS9H " This capacitor type EMI suppression filter has a large noise suppression effect at frequencies ranging from a few MHz to hundreds of MHz. This type of filter is used widely as a universal, high performance EMI suppression component. " The chip EMIFILr incorporates a builtin threeterminal capacitor, eliminating the lead wire and thereby increasing the highfrequency performance characteristic. " The Ttype chip EMIFILr is a chip EMI suppression filter with a builtin feedthru capacitor. The use of ferrite beads on input and output terminals minimizes resonance with surrounding circuits. " Whatever the situation, 3terminal construction reduces residual inductance, thereby substantially improving noise suppression at frequencies over MHz. [Comparison of Insertion Loss Characteristics] Insertion Loss [db] 2 4 6 C 22PF 3Terminal Capacitor (Builtin Bead) (DSS9HB32E222Q55) 8 5 Frequency [MHz] 2Terminal Capacitor 3Terminal Capacitor (DSN9HB32E222Q55) Ideal Characteristics of Capacitor 5 5 A 3terminal capacitor has a higher self resonance frequency than a general 2terminal type and exhibits effective noise suppression at high frequency. 7
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line ochip EMIFILr for Signal Line ochip EMIFILr with Waveform Distortion Suppressing Function Chip EMIFILr for Signal Line...P.3 39 P.53 56 P.8 85 Chip EMIFILr with Waveform Distortion Suppressing Function...P.75 8 NFW3S NFL8ST NFL8SP NFL2S BLM8B/8HD BLM2B NF2G NFA3G " Highspeed signal application EMIFILr are high performance EMI suppression filters which increase the slope of insertion loss frequency characteristic curves (shape factor), thereby improving noise and signal separation. These are used for high speed signal applications in which noise and signal frequency approach the same value. To avoid the elimination of both the noise and specific signal components, 3terminal capacitors and other components are applied. An NFW3S with a builtin capacitor and an inductor type BLMB are available. BLM8HD has additional performance for suppressing GHz range noise after cut off frequency. " The EMIFILr with waveform distortion suppressing function suppresses waveform distortion caused by the resonance of digital ICs and surrounding circuits. [Comparison of Insertion Loss Characteristics] Insertion Loss [db] NFW3S Conventional Type 2 4 6 8 5 5 5 2 Frequency [MHz] [Waveform change when filter is inserted] Conventional Type (Chip 3terminal Capacitor) EMIFILr for Signal Line NFW3S series 8
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line ochip Common Mode Choke Coil ocommon Mode Choke Coil Chip Common Mode Choke Coil...P.97 4 Common Mode Choke Coil...P.28 DLPS DLP3S DLP3D DLM2HG DLW2S DLW2H DLW3S PLT9H DLW5AH DLW5BS " These choke coils reduce common mode noise, which causes problems on balanced transmission lines, and are effective against common mode noise in the several MHz to several MHz frequency range. They are ideally suited for noise suppression on DC power supply lines and interface cables. [Construction of Common Mode Choke Coil] Current of Common Mode (Noise) Current of Differential Mode (Signal) [Equivalent Circuit] [ImpedanceFrequency Characteristics (DLW3S)] DLW3SN222SQ2 Common mode DLW3SN2SQ2 DLW3SN6SQ2 DLW3SN26SQ2 DLW3SN6SQ2 DLW3SN9SQ2 SN222 SN2 SN6 SN26 SN6 SN9 Differential mode. 9
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line ochip EMIGUADr oemiguadr Chip EMIGUADr...P.94 95 EMIGUADr...P.8 24 VFM4 VF3V VFS6V VFS9V " EMIGUADr eliminates both surge noises and EMI noises due to its dielectric varistor material. " Effective when high frequency noise and high voltage surge suppression are required, and also in situations when surging starts at extremely high speeds. This type of surging cannot be eliminated with general type varistors. " VFM4 is chip type of EMIGUADr. [Construction of EMIGUADr (VFS9V)], Varistor Electrode Ferrite Lead!Surge Absorption Effect of EMIGUADr Type of Filter Surge Absorption Effect of EMIGUADr 4kV No filter 5V /div kv ns 5ns/div 4ns 4kV 3terminal capacitor is used to suppress the surge. 5V /div kv ns 5ns/div 4ns 4kV EMIGUADr is used to suppressthe surge. (VFS6V) 5V /div kv ns 5ns/div 4ns
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Outline of EMI Suppression Filters (EMIFILr) for DC Line oblock Type EMIFILr Block Type EMIFILr...P.25 26 BN2 BN3 BN5 " Block type EMIFILr are resin encased, builtin, high performance EMI suppression filters, which use a feedthru capacitor having excellent high frequency characteristics. " Used when the noise frequency is high, or when extreme countermeasures are required. " The high performance EMIFILr BN series exhibits significant noise suppression effects over a wide frequency band (extending from khz to GHz) in DC power lines. [Equivalent Circuit (BN Series)] B PSG L L2 C L3 PSG: Power Supply Ground CG: Circuit Ground CB: Circuit + B C2 CB CG [Insertion Loss Characteristics] Insertion Loss [db] 2 4 6 8 BN2 (BN5) BN3... Frequency [MHz]
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Ferrite Beads Part Numbering Chip Ferrite Beads (Global Part Number) BL q M w 8 AG 2 S N D e r t y u i o qproduct ID timpedance Product ID BL Chip Ferrite Beads Expressed by three figures. The unit is in ohm (Ω). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. wtype yperformance Code A Type Array Type Expressed by a letter. Ex.) Code Performance M Monolithic Type S Sn Plating edimensions (LgW) ucategory Code Dimensions (LgW) EIA Code Category 3.6g.3mm 2 N Standard Type 5.g.5mm 42 H for Heavyduty 8 2A.6g.8mm 2.g.mm 63 84 inumber of Circuits 2 2.g.25mm 85 Code Number of Circuits 3 3.2g.6mm 26 Circuit 4 4.5g.6mm 86 4 4 Circuits rcharacteristics/applications Code * Characteristics/Applications AF AG for General Use AJ AH BA BB for Highspeed Signal Lines BD BE PF for Power Supplies PG K for Digital Interface HG for GHz Band General Use EG for GHz Band General Use (Low DC esistance type) HB for GHz Band Highspeed Signal Line HD HK for GHz Band Digital Interface * Frequency characteristics vary with each code. Series BLM3/BLM4 BLM3/BLM5/BLM8/BLM2/BLM3/BLA2A/BLA3 BLM2/BLM3 BLM2 BLM8 BLM5/BLM8/BLM2/BLA2A BLM5/BLM8/BLM2/BLA3 BLM3 BLM4 BLM8/BLM2/BLM3/BLM4 BLM8/BLM2 BLM8 BLM8 BLM8 opackaging Code K L B J D C * BLM2BD222SN/BLM2BD272SN only. *2 Except BLM2BD222SN/BLM2BD272SN Packaging Plastic Taping (ø33mm eel) Plastic Taping (ø8mm eel) Bulk Paper Taping (ø33mm eel) Paper Taping (ø8mm eel) Bulk Case Series BLM3/BLM4/BLM2 * All series BLM5/BLM8/BLM2*2 /BLA3 BLM3/BLM5/BLM8/BLM2*2 /BLA2A/BLA3 BLM5/BLM8 2
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. OnBoard Type (DC) EMI Suppression Filters(EMIFILr) Chip Ferrite Bead BLM Series Essential for Noise Suppression in High Speed Signal Lines and DC Power Lines The chip ferrite bead BLM series comprises ferrite beads in the shape of a chip. This ferrite bead generates a high impedance which at high frequencies mainly consists of a resistance element. The BLM series is effective in circuits without stable ground lines because the BLM series does not need a connection to ground. Chip sizes of.6.3,..5,.6.8, 2..25, 3.2.6 and 4.5.6mm are cataloged. (The BLA series of array type chip ferrite beads is also cataloged.) The nickel barrier structure of the external electrodes provides excellent solder heat resistance.!features The BLM series comprises the series (for digital interface), the A series (for standard), the B series (for high speed signal), the P series (for large current), and the H/E series (for GHz range noise suppression).. BLM series For Digital Interface The BLM series can be used in Digital Interface. esistance of BLM series especially grows in the lower frequency range. Therefore BLM series is less effective for digital signal waveform at low frequency range and can suppress the ringing. 2. BLMA series For Standard The BLMA series generates an impedance from the relatively low frequencies. Therefore the BLMA series is effective in noise suppression in the wide frequency range (3MHz several hundred MHz). 3. BLMB series For High Speed Signal The BLMB series can minimize attenuation of the signal waveform due to its sharp impedance characteristics. Various impedances are available to match signal frequency. 4. BLMP series For Large Current The BLMP series can be used in high current circuits due to its low DC resistance. It can match power lines to a maximum of 6A DC (BLM4P). 5. BLM8H/E series For GHz ange Noise Suppression The BLM8H/E series has a modified internal electrode structure that minimizes stray capacitance and increases the effective frequency range. [Impedance Characteristics] 8 BLM8HG2SN 5 BLM8BD2SN 2 9 6 BLM8K2SN 3 BLM8AG2SN 3
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc.!impedance Map at MHz 2 7 6 22 2 7 6 47 33 22 5 2 33 22 5 2 63 5 68 22 326 465 5 68 22 326 68 22 68 22 326 456 68 For Standard BLMppA 6 6 47 4 7 26 5 8 6 47 22 75 47 25 22 8 5 6 47 42 33 22 5 4 2 75 6 47 22 5 27 225 22 8 5 75 6 47 42 33 22 5 2 75 6 For High Speed Signal BLMppB 6 6 47 22 2 6 47 22 2 For Digital Interface BLMpp 8 (.5A) 2 (2A) 6 (.5A) 33 (3A) 3 (A) 33 (.5A) 22 (2A) 6 (3A) 3 (3A) 22 (6A) 6 (.5A) 39 (2A) 2 (3A) 5 (3A) 33 (6A) For Large Current BLMppP ( )=ated Current (.5A) 47 (2A) 8 (3A) 8 (A) 75 (3A) 6 (6A) 6 47 39 33 22 2 GHz ange Noise Suppression Type BLM8H/E size (mm) 4
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc.!blm Series Size (inches) 42 63 Type 63 For Standard For Standard For High Speed Signal (Sharp impedance characteristics) For Standard For High Speed Signal (Sharp impedance characteristics) Part Number BLM3AGSN BLM3AG7SN BLM3AG2SN BLM5AGSN BLM5AG7SN BLM5AG2SN BLM5AG22SN BLM5AG6SN BLM5AG2SN BLM5BB5SN BLM5BBSN BLM5BB22SN BLM5BB47SN BLM5BB75SN BLM5BB2SN BLM5BB22SN BLM5BD47SN BLM5BD6SN BLM5BD2SN BLM8AG2SN BLM8AG5SN BLM8AG22SN BLM8AG33SN BLM8AG47SN BLM8AG6SN BLM8AG2SN BLM8BA5SN BLM8BB5SN BLM8BASN BLM8BBSN BLM8BA22SN BLM8BB22SN BLM8BA47SN BLM8BB47SN BLM8BB6SN BLM8BA75SN BLM8BB75SN BLM8BA2SN BLM8BB2SN BLM8BD2SN BLM8BB4SN BLM8BB5SN BLM8BD5SN BLM8BB22SN BLM8BD22SN BLM8BB33SN BLM8BD33SN BLM8BD42SN BLM8BB47SN BLM8BD47SN BLM8BD6SN BLM8BD2SN BLM8BD52SN BLM8BD82SN BLM8BD222SN BLM8BD252SN at MHz at GHz (Typ.) 7 (Typ.) 2±25% (Typ.) 7 (Typ.) 2±25% 22±25% 6±25% ±25% 5±25% ±25% 22±25% 47±25% 75±25% 2±25% 22±25% 47±25% 6±25% ±25% 2±25% 5±25% 22±25% 33±25% 47±25% 6±25% ±25% 5±25% ±25% 22±25% 47±25% 6±25% 75±25% 2±25% 4±25% 5±25% 22±25% 33±25% 42±25% 47±25% 6±25% ±25% 5±25% 8±25% 22±25% 25±25% ated Current (ma) 5 2 2 5 3 2 5 3 2 2 5 7 5 3 5 2 3 2 2 5 2 2 5 Continued on the following page. 5
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Continued from the preceding page. Size (inches) Type Part Number at MHz at GHz ated Current (ma) 63 85 GHz ange For Digital Interface For Large Current For Standard For Standard For High Speed Signal For Digital Interface For Standard (Low DC esistance Type) BLM8K2SN BLM8K22SN BLM8K47SN BLM8K6SN BLM8K2SN BLM8PG3SN BLM8PG33SN BLM8PG6SN BLM8PG2SN BLM8PG8SN BLM8HG47SN BLM8HG6SN BLM8HG2SN BLM8HB2SN BLM8HB22SN BLM8HB33SN BLM8HD47SN BLM8HD6SN BLM8HD2SN BLM8HK33SN BLM8HK47SN BLM8HK6SN BLM8HK2SN BLM8EGTN BLM8EG2SN BLM8EG39TN BLM8EG6SN BLM2AG2SN BLM2AG5SN BLM2AG22SN BLM2AG33SN BLM2AJ4SN BLM2AG47SN BLM2AG6SN BLM2AJ6SN BLM2AG2SN BLM2AH2SN 2±25% 22±25% 47±25% 6±25% ±25% 3 (Typ.) 33±25% 6 (Typ.) 2±25% 8±25% 47±25% 6±25% ±25% 2±25% 22±25% 33±25% 47±25% 6±25% ±25% 33±25% 47±25% 6±25% ±25% ±25% 2±25% 39±25% 6±25% 2±25% 5±25% 22±25% 33±25% 4±25% 47±25% 6±25% ±25% 6 (Typ.) 7 (Typ.) (Typ.) 5±4% ±4% 6±4% (Typ.) 2 (Typ.) 7 (Typ.) 4±4% 6±4% 7±4% 2±4% 4 (Typ.) 45 (Typ.) 52 (Typ.) 7 (Typ.) 2 3* 5 2* 5* 2 2 5 5 2 5 2* 2* 5 3 2 * Please see P. 5 "Derating of ated Current". Continued on the following page. 6
!Note C3E9.pdf 3.3.2!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog catalog to prevent to prevent smoking smoking and/or and/or burning, burning, etc. etc. Continued from the preceding page. Size (inches) Type Part Number at MHz at GHz ated Current (ma) 85 For High Speed Signal (Sharp impedance characteristics) For Digital Interface For Large Current For Standard BLM2BB5SN BLM2BB6SN BLM2BB75SN BLM2BB2SN BLM2BD2SN BLM2BB5SN BLM2BD5SN BLM2BB2SN BLM2BB22SN BLM2BD22SN BLM2BB33SN BLM2BD33SN BLM2BD42SN BLM2BB47SN BLM2BD47SN BLM2BD6SN BLM2BD75SN BLM2BD2SN BLM2BD52SN BLM2BD82SN BLM2BD222SN BLM2BD222TN BLM2BD272SN BLM2K2SN BLM2K22SN BLM2K47SN BLM2K6SN BLM2K2SN BLM2PG22SN BLM2PG3SN BLM2PG6SN BLM2PG22SN BLM2PG33SN BLM3AJ26SN BLM3AF7SN BLM3AJ6SN 5±25% 6±25% 75±25% 2±25% 5±25% 2±25% 22±25% 33±25% 42±25% 47±25% 6±25% 75±25% ±25% 5±25% 8±25% 225 (Typ.) 22±25% 27±25% 2±25% 22±25% 47±25% 6±25% ±25% 22±25% 3 (Typ.) 6±25% 22±25% 33±25% 26±25% 7±25% 6±25% 5 2 2 6* 3* 2* 5* 5 2 26 86 For High Speed Signal (Sharp impedance characteristics) For Large Current For Standard For Large Current BLM3BE6FN BLM3PG33SN BLM3PG5SN BLM3PG2SN BLM3PG39SN BLM3PG6SN BLM4AF8SN BLM4AF5SN BLM4PG6SN BLM4PG75SN BLM4PF8SN BLM4PG8SN BLM4PG47SN BLM4PG2SN 6±25% 33±25% 5 (Typ.) 2±25% 39±25% 6±25% 8±25% 5±25% 6 (Typ.) 75 (Typ.) 8 (Typ.) 8±25% 47±25% ±25% 3 6* 3* 2* 5* 5 2 6* 3* * 3* 2* 5* * Please see P.5 "Derating of ated Current". 7
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Ferrite Beads BLM3/BLM5/BLM8/BLM2/BLM3/BLM4 Series Features (BLM_A Series) The chip ferrite bead BLM series comprises ferrite beads in the shape of a chip. This ferrite bead generates a high impedance which at high frequency mainly consists of a resistance element. The BLM series is effective in circuits without stable ground lines because the BLM series does not need a connection to ground. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. BLM_A series generates an impedance from the relatively low frequencies. Therefore BLM_A series is effective in noise suppression in a wide frequency range (3MHz several hundred MHz). The small size of BLM3 series (.6x.3mm) is suitable for noise suppression in small equipment such as PA modules for cellular phones. BLM3A Series (2 Size) Equivalent Circuit (esistance element becomes dominant at high frequencies.).6±.3.3±.3.3±.3.5±.5 : electrode (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM3AGSN (Typ.) 5. 55 to 25 BLM3AG7SN 7 (Typ.) 2.5 55 to 25 BLM3AG2SN 2 ±25% 2.8 55 to 25 8
!Note C3E9.pdf 3.3.2 ImpedanceFrequency (Typical) 3 BLM3 Series 25 2 5 BLM3AG7SN BLM3AG2SN 5 BLM3AGSN 2 ImpedanceFrequency Characteristics 2 BLM3AGSN 5 BLM3AG7SN 5 2 9 6 5 3 2 2 3 BLM3AG2SN 25 2 5 5 2 BLM5A Series (42 Size).25±..5±.5.±.5.5±.5 BLM5A Series (in mm) 9
!Note C3E9.pdf 3.3.2 Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM5AGSN (Typ.).5 55 to 25 BLM5AG7SN 7 (Typ.) 5.5 55 to 25 BLM5AG2SN 2 ±25% 5.25 55 to 25 BLM5AG22SN 22 ±25% 3.35 55 to 25 BLM5AG6SN 6 ±25% 3.6 55 to 25 BLM5AG2SN ±25% 2. 55 to 25 ImpedanceFrequency (Typical) BLM5A Series 2 BLM5AG2SN Impedance (ohm) 8 6 4 2 BLM5AG6SN BLM5AG22SN BLM5AG2SN BLM5AG7SN BLM5AGSN ImpedanceFrequency Characteristics BLM5AGSN BLM5AG7SN 2 2 Impedance (ohm) 5 Impedance (ohm) 8 6 4 5 2 2 BLM5AG2SN 4 BLM5AG22SN 5 3 Impedance (ohm) Impedance (ohm) 2 5 Continued on the following page. 2
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 8 BLM5AG6SN 2 BLM5AG2SN 6 9 4 6 2 3 BLM8A Series (63 Size).4±.2.8±.5.6±.5.8±.5 BLM8A Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8AG2SN 2 ±25% 2.2 55 to 25 BLM8AG5SN 5 ±25% 2.25 55 to 25 BLM8AG22SN 22 ±25% 2.3 55 to 25 BLM8AG33SN 33 ±25% 2.45 55 to 25 BLM8AG47SN 47 ±25% 2.5 55 to 25 BLM8AG6SN 6 ±25% 2.5 55 to 25 BLM8AG2SN ±25%.7 55 to 25 ImpedanceFrequency (Typical) BLM8A Series 2 BLM8AG2SN 9 6 3 BLM8AG6SN BLM8AG47SN BLM8AG33SN BLM8AG22SN BLM8AG5SN BLM8AG2SN 2
!Note C3E9.pdf 3.3.2 ImpedanceFrequency Characteristics 2 BLM8AG2SN 4 BLM8AG5SN 5 3 5 2 BLM8AG22SN BLM8AG33SN 4 6 3 45 2 3 5 8 BLM8AG47SN 8 BLM8AG6SN 6 6 4 4 2 2 2 BLM8AG2SN 9 6 3 22
!Note C3E9.pdf 3.3.2 BLM2A Series (85 Size).5±.2 *2.85±.2 * 2.±.2.25±.2 BLM2A Series * BLM2BD222SN / 2BD272SN :.25±.2 *2 BLM2BD272SN:.3±.2 EIA CODE : 85 in mm Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM2AG2SN 2 ±25% 2.5 55 to 25 BLM2AG5SN 5 ±25% 2.5 55 to 25 BLM2AG22SN 22 ±25% 2.2 55 to 25 BLM2AG33SN 33 ±25% 2.25 55 to 25 BLM2AJ4SN 4 ±25% 2.85 55 to 25 BLM2AG47SN 47 ±25% 2.25 55 to 25 BLM2AG6SN 6 ±25% 2.3 55 to 25 BLM2AJ6SN 6 ±25% 2. 55 to 25 BLM2AG2SN ±25% 2.45 55 to 25 BLM2AH2SN ±25% 2.45 55 to 85 ImpedanceFrequency (Typical) 2 BLM2A Series 9 6 BLM2AH2SN BLM2AJ6SN BLM2AJ4SN BLM2AG2SN BLM2AG6SN BLM2AG47SN BLM2AG33SN BLM2AG22SN BLM2AG5SN BLM2AG2SN 3 ImpedanceFrequency Characteristics 2 BLM2AG2SN 2 BLM2AG5SN 5 5 5 5 Continued on the following page. 23
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 4 BLM2AG22SN 4 BLM2AG33SN 3 3 2 2 5 BLM2AJ4SN 8 BLM2AG47SN 4 6 Impedance (ohm) 3 2 4 2 8 BLM2AG6SN 8 BLM2AJ6SN 6 4 6 4 2 2 2 BLM2AG2SN 2 BLM2AH2SN 9 9 6 6 3 3 24
!Note C3E9.pdf 3.3.2 BLM3A Series (26 Size).7±.3 *.±.2 3.2±.2.6±.2 * BLM3AF7SN :.6±.2 BLM3A Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM3AJ26SN 26 ±25% 5.5 55 to 25 BLM3AF7SN 7 ±25% 2.5 55 to 25 BLM3AJ6SN 6 ±25% 2.9 55 to 25 ImpedanceFrequency (Typical) 8 BLM3A Series ImpedanceFrequency Characteristics 4 BLM3AJ26SN 6 BLM3AJ6SN 3 Impedance (ohm) 4 2 2 BLM3AF7SN BLM3AJ26SN BLM3AF7SN 8 BLM3AJ6SN 75 5 6 4 25 2 25
!Note C3E9.pdf 3.3.2 BLM4A Series (86 Size).7±.3.6±.2 4.5±.2.6±.2 BLM4A Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM4AF8SN 8 ±25% 5. 55 to 25 BLM4AF5SN 5 ±25% 2.5 55 to 25 ImpedanceFrequency (Typical) 2 BLM4A Series 5 BLM4AF5SN Impedance (ohm) BLM4AF8SN 5 ImpedanceFrequency Characteristics BLM4AF8SN 2 BLM4AF5SN 75 5 5 25 5 26
!Note C3E9.pdf 3.3.2 Features (BLM_B Series) The chip ferrite bead BLM series comprises ferrite beads in the shape of a chip. This ferrite bead generates a high impedance which at high frequencies mainly consists of a resistance element. The BLM series is effective in circuits without stable ground lines because the BLM series does not need a connection to ground. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. The BLM_B series can minimize attenuation of the signal waveform due to its sharp impedance characteristics. Various impedances are available to match signal frequency. Equivalent Circuit (esistance element becomes dominant at high frequencies.) BLM5B Series (42 Size).25±..5±.5.±.5.5±.5 BLM5B Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM5BB5SN 5 ±25% 5.8 55 to 25 BLM5BBSN ±25% 3. 55 to 25 BLM5BB22SN 22 ±25% 3.2 55 to 25 BLM5BB47SN 47 ±25% 3.35 55 to 25 BLM5BB75SN 75 ±25% 3.4 55 to 25 BLM5BB2SN 2 ±25% 3.55 55 to 25 BLM5BB22SN 22 ±25% 2.8 55 to 25 BLM5BD47SN 47 ±25% 2.6 55 to 25 BLM5BD6SN 6 ±25% 2.65 55 to 25 BLM5BD2SN ±25% 2.9 55 to 25 ated current is 6A for taping type. 27
!Note C3E9.pdf 3.3.2 ImpedanceFrequency (Typical) 8 BLM5BB Series 6 BLM5BD Series 7 BLM5BB22SN BLM5BD2SN 6 2 Impedance (ohm) 5 4 3 2 BLM5BB2SN BLM5BB75SN BLM5BB47SN BLM5BB22SN BLM5BBSN BLM5BB5SN 8 4 BLM5BD6SN BLM5BD47SN ImpedanceFrequency Characteristics BLM5BB5SN BLM5BBSN 3 6 25 5 Impedance (ohm) 2 5 Impedance (ohm) 4 3 2 5 BLM5BB22SN 2 BLM5BB47SN 8 5 Impedance (ohm) 6 4 Impedance (ohm) 2 5 4 BLM5BB75SN 6 BLM5BB2SN 3 45 Impedance (ohm) 2 Impedance (ohm) 3 5 28 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 8 BLM5BB22SN BLM5BD47SN 6 75 Impedance (ohm) 4 5 2 25 BLM5BD6SN BLM5BD2SN 2 6 9 2 6 8 3 4 29
!Note C3E9.pdf 3.3.2 BLM8B Series (63 Size).4±.2.6±.5.8±.5.8±.5 BLM8B Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8BA5SN 5 ±25% 5.2 55 to 25 BLM8BB5SN 5 ±25% 7. 55 to 25 BLM8BASN ±25% 5.25 55 to 25 BLM8BBSN ±25% 5.5 55 to 25 BLM8BA22SN 22 ±25% 5.35 55 to 25 BLM8BB22SN 22 ±25% 5.25 55 to 25 BLM8BA47SN 47 ±25% 3.55 55 to 25 BLM8BB47SN 47 ±25% 5.3 55 to 25 BLM8BB6SN 6 ±25% 2.35 55 to 25 BLM8BA75SN 75 ±25% 3.7 55 to 25 BLM8BB75SN 75 ±25% 2.35 55 to 25 BLM8BA2SN 2 ±25% 2.9 55 to 25 BLM8BB2SN 2 ±25% 2.5 55 to 25 BLM8BD2SN 2 ±25% 2.4 55 to 25 BLM8BB4SN 4 ±25% 2.55 55 to 25 BLM8BB5SN 5 ±25% 2.55 55 to 25 BLM8BD5SN 5 ±25% 2.4 55 to 25 BLM8BB22SN 22 ±25% 2.65 55 to 25 BLM8BD22SN 22 ±25% 2.45 55 to 25 BLM8BB33SN 33 ±25% 2.75 55 to 25 BLM8BD33SN 33 ±25% 2.5 55 to 25 BLM8BD42SN 42 ±25% 2.55 55 to 25 BLM8BB47SN 47 ±25% 5. 55 to 25 BLM8BD47SN 47 ±25% 2.55 55 to 25 BLM8BD6SN 6 ±25% 2.65 55 to 25 BLM8BD2SN ±25%.85 55 to 25 BLM8BD52SN 5 ±25% 5.2 55 to 25 BLM8BD82SN 8 ±25% 5.5 55 to 25 BLM8BD222SN 22 ±25% 5.5 55 to 25 BLM8BD252SN 25 ±25% 5.5 55 to 25 3
!Note C3E9.pdf 3.3.2 ImpedanceFrequency (Typical) 6 BLM8BA Series BLM8BA Series 45 75 3 BLM8BA22SN BLM8BASN 5 BLM8BA2SN 5 BLM8BA5SN 25 BLM8BA75SN BLM8BA47SN 2 Frequency(MHz) 2 Frequency(MHz) BLM8BB Series BLM8BB Series 2 2 5 5 BLM8BB47SN BLM8BB22SN BLM8BBSN BLM8BB5SN 5 5 BLM8BB47SN BLM8BB33SN BLM8BB22SN BLM8BB5SN BLM8BB4SN BLM8BB2SN BLM8BB75SN BLM8BB6SN 28 2 4 7 BLM8BD Series BLM8BD252SN BLM8BD222SN BLM8BD82SN BLM8BD52SN BLM8BD2SN BLM8BD6SN BLM8BD47SN BLM8BD42SN BLM8BD33SN BLM8BD22SN BLM8BD5SN BLM8BD2SN ImpedanceFrequency Characteristics BLM8BA5SN 4 BLM8BB5SN 75 3 5 2 25 2 Frequency(MHz) Continued on the following page. 3
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 2 BLM8BASN 4 BLM8BBSN 5 3 2 5 2 Frequency(MHz) BLM8BA22SN BLM8BB22SN 6 45 75 3 5 5 25 2 Frequency(MHz) BLM8BA47SN BLM8BB47SN 6 2 2 5 8 4 5 2 Frequency(MHz) 4 BLM8BB6SN 6 BLM8BA75SN 3 45 2 3 5 2 Frequency(MHz) 32 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 4 BLM8BB75SN BLM8BA2SN 3 75 2 5 25 2 Frequency(MHz) 6 BLM8BB2SN 4 BLM8BD2SN 45 3 3 2 5 6 BLM8BB4SN 6 BLM8BB5SN 45 45 3 3 5 5 6 BLM8BD5SN 8 BLM8BB22SN 45 6 3 5 4 2 Continued on the following page. 33
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 8 BLM8BD22SN 6 BLM8BB33SN 6 2 4 8 2 4 8 BLM8BD33SN BLM8BD42SN 6 75 4 2 5 25 2 BLM8BB47SN 2 BLM8BD47SN 5 8 6 5 4 2 BLM8BD6SN 2 BLM8BD2SN 9 5 6 3 5 34 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics BLM8BD52SN 2 24 BLM8BD82SN 5 8 2 5 6 24 BLM8BD222SN 28 BLM8BD252SN 8 2 2 4 6 7 35
!Note C3E9.pdf 3.3.2 BLM2B Series (85 Size).5±.2 *2.85±.2 * 2.±.2.25±.2 BLM2B Series * BLM2BD222SN / 2BD272SN :.25±.2 *2 BLM2BD272SN:.3±.2 EIA CODE : 85 in mm Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM2BB5SN 5 ±25% 5.7 55 to 25 BLM2BB6SN 6 ±25% 2.2 55 to 25 BLM2BB75SN 75 ±25% 2.25 55 to 25 BLM2BB2SN 2 ±25% 2.25 55 to 25 BLM2BD2SN 2 ±25% 2.25 55 to 25 BLM2BB5SN 5 ±25% 2.25 55 to 25 BLM2BD5SN 5 ±25% 2.25 55 to 25 BLM2BB2SN 2 ±25% 2.35 55 to 25 BLM2BB22SN 22 ±25% 2.35 55 to 25 BLM2BD22SN 22 ±25% 2.25 55 to 25 BLM2BB33SN 33 ±25% 2.4 55 to 25 BLM2BD33SN 33 ±25% 2.3 55 to 25 BLM2BD42SN 42 ±25% 2.3 55 to 25 BLM2BB47SN 47 ±25% 2.45 55 to 25 BLM2BD47SN 47 ±25% 2.35 55 to 25 BLM2BD6SN 6 ±25% 2.35 55 to 25 BLM2BD75SN 75 ±25% 2.4 55 to 25 BLM2BD2SN ±25% 2.4 55 to 25 BLM2BD52SN 5 ±25% 2.45 55 to 25 BLM2BD82SN 8 ±25% 2.5 55 to 25 BLM2BD222TN 22 ±25% 2.6 55 to 25 BLM2BD222SN 225 (Typ.) 2.6 55 to 25 BLM2BD272SN 27 ±25% 2.8 55 to 25 ImpedanceFrequency (Typical) BLM2BB Series BLM2BD Series 2 32 BLM2BD272SN 5 5 BLM2BB47SN BLM2BB33SN BLM2BB22SN BLM2BB5SN BLM2BB2SN BLM2BB6SN BLM2BB5SN BLM2BB2SN BLM2BB75SN 24 6 8 BLM2BD52SN BLM2BD2SN BLM2BD75SN BLM2BD6SN BLM2BD47SN BLM2BD42SN BLM2BD33SN BLM2BD22SN BLM2BD5SN BLM2BD2SN BLM2BD222SN BLM2BD222TN BLM2BD82SN Continued on the following page. 36
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 4 BLM2BB5SN 4 BLM2BB6SN 3 3 2 2 4 BLM2BB75SN 6 BLM2BB2SN 3 45 2 3 5 4 BLM2BD2SN 8 BLM2BB5SN 3 6 2 4 2 4 BLM2BD5SN 2 BLM2BB2SN 3 9 2 6 3 Continued on the following page. 37
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics BLM2BB22SN 6 BLM2BD22SN 75 45 5 25 3 5 2 BLM2BB33SN 8 BLM2BD33SN 9 6 6 4 3 2 BLM2BD42SN BLM2BB47SN 2 75 5 5 25 5 2 BLM2BD47SN 2 BLM2BD6SN 9 9 6 6 3 3 38 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 6 BLM2BD75SN 2 BLM2BD2SN 2 5 8 4 5 24 BLM2BD52SN 24 BLM2BD82SN 8 2 6 8 2 6 24 BLM2BD222TN 32 BLM2BD222SN 8 24 2 6 6 8 32 BLM2BD272SN 24 6 8 39
!Note C3E9.pdf 3.3.2 BLM3B Series (26 Size).7±.3.±.2 3.2±.2.6±.2 in mm BLM3B Series Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM3BE6FN 6 ±25% 3.35 55 to 25 ImpedanceFrequency (Typical) 8 BLM3B Series Impedance (ohm) 6 4 BLM3BE6FN 2 ImpedanceFrequency Characteristics 8 BLM3BE6FN 6 4 2 4
!Note C3E9.pdf 3.3.2 Features (BLM_ Series) The chip ferrite bead BLM series comprises ferrite beads in the shape of a chip. This ferrite bead generates a high impedance which at high frequencies mainly consists of a resistance element. The BLM series is effective in circuits without stable ground lines because the BLM series does not need a connection to ground. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. The BLM_ series can be used in a digital interface. esistance of BLM_ series especiallly grows in the lower frequency range. Therefore BLM_ series is less effective for digital signal waveform at low frequency range and can suppress the ringing. BLM8 Series (63 Size) Equivalent Circuit (esistance element becomes dominant at high frequencies.).4±.2.8±.5.6±.5.8±.5 BLM8 Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8K2SN 2 ±25% 2.25 55 to 25 BLM8K22SN 22 ±25% 2.3 55 to 25 BLM8K47SN 47 ±25% 2.5 55 to 25 BLM8K6SN 6 ±25% 2.6 55 to 25 BLM8K2SN ±25% 2.8 55 to 25 ImpedanceFrequency (Typical) 2 BLM8 Series 9 6 BLM8K6SN BLM8K47SN BLM8K22SN BLM8K2SN BLM8K2SN 3 4
!Note C3E9.pdf 3.3.2 ImpedanceFrequency Characteristics 2 BLM8K2SN 4 BLM8K22SN 5 3 2 5 6 BLM8K47SN BLM8K6SN 45 75 3 5 5 25 2 BLM8K2SN 9 6 3 42
!Note C3E9.pdf 3.3.2 BLM2 Series (85 Size).5±.2.85±.2 2.±.2.25±.2 BLM2 Series EIA CODE : 85 (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM2K2SN 2 ±25% 2.5 55 to 25 BLM2K22SN 22 ±25% 2.2 55 to 25 BLM2K47SN 47 ±25% 2.25 55 to 25 BLM2K6SN 6 ±25% 2.3 55 to 25 BLM2K2SN ±25% 2.5 55 to 25 ImpedanceFrequency (Typical) 2 BLM2 Series 9 BLM2K6SN BLM2K47SN BLM2K2SN 6 BLM2K22SN BLM2K2SN 3 ImpedanceFrequency Characteristics 2 BLM2K2SN 3 BLM2K22SN 5 225 5 5 75 Continued on the following page. 43
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 6 BLM2K47SN BLM2K6SN 45 75 3 5 5 25 2 BLM2K2SN 9 6 3 44
!Note C3E9.pdf 3.3.2 Features (BLM_P Series) The chip ferrite bead BLM series comprises ferrite beads in the shape of a chip. This ferrite bead generates a high impedance which at high frequencies mainly consists of a resistance element. The BLM series is effective in circuits without stable ground lines because the BLM series does not need a connection to ground. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. The BLM_P series can be used in high current circuits due to its low DC resistance. It can match power lines to a maximum of 6A DC (BLM4P). Equivalent Circuit (esistance element becomes dominant at high frequencies.) BLM8P Series (63 Size).4±.2.8±.5.6±.5.8±.5 BLM8P Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8PG3SN 3 (Typ.).5 55 to 25 BLM8PG33SN 33 ±25% 3.25 55 to 25 BLM8PG6SN 6 (Typ.) 5. 55 to 25 BLM8PG2SN 2 ±25% 2.5 55 to 25 BLM8PG8SN 8 ±25% 5.9 55 to 25 At rated current upper than 5mA, derating is required. Please refer P. 5, "Derating of ated Current". ImpedanceFrequency (Typical) 3 BLM8P Series 24 BLM8PG8SN 8 2 6 BLM8PG2SN BLM8PG6SN BLM8PG33SN BLM8PG3SN 45
!Note C3E9.pdf 3.3.2 ImpedanceFrequency Characteristics 8 BLM8PG3SN 6 BLM8PG33SN 6 45 4 2 3 5 BLM8PG6SN BLM8PG2SN 2 75 5 5 25 5 BLM8PG8SN 28 2 4 7 46
!Note C3E9.pdf 3.3.2 BLM2P Series (85 Size).5±.2.85±.2 2.±.2.25±.2 BLM2P Series EIA CODE : 85 (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM2PG22SN 22 ±25% 6. 55 to 25 BLM2PG3SN 3 (Typ.) 3.5 55 to 25 BLM2PG6SN 6 ±25% 3.25 55 to 25 BLM2PG22SN 22 ±25% 2.5 55 to 25 BLM2PG33SN 33 ±25% 5.9 55 to 25 At rated current upper than 5mA, derating is required. Please refer P. 5, "Derating of ated Current". ImpedanceFrequency (Typical) 6 BLM2P Series 45 3 5 BLM2PG33SN BLM2PG22SN BLM2PG6SN BLM2PG3SN BLM2PG22SN ImpedanceFrequency Characteristics 4 BLM2PG22SN 6 BLM2PG3SN 3 45 2 3 5 Continued on the following page. 47
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 2 BLM2PG6SN 4 BLM2PG22SN 9 3 6 2 3 6 BLM2PG33SN 45 3 5 BLM3P Series (26 Size).7±.3.±.2 3.2±.2.6±.2 in mm BLM3P Series Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM3PG33SN 33 ±25% 6. 55 to 25 BLM3PG5SN 5 (Typ.) 3.25 55 to 25 BLM3PG2SN 2 ±25% 3.25 55 to 25 BLM3PG39SN 39 ±25% 2.5 55 to 25 BLM3PG6SN 6 ±25% 5.9 55 to 25 At rated current upper than 5mA, derating is required. Please refer P. 5, "Derating of ated Current". 48
!Note C3E9.pdf 3.3.2 ImpedanceFrequency (Typical) 7 BLM3P Series 6 BLM3PG6SN Impedance (ohm) 5 4 3 BLM3PG39SN BLM3PG2SN BLM3PG5SN 2 BLM3PG33SN ImpedanceFrequency Characteristics 6 BLM3PG33SN 8 BLM3PG5SN 45 6 3 4 5 2 BLM3PG2SN BLM3PG39SN 2 6 5 45 3 5 5 8 BLM3PG6SN 6 4 2 49
!Note C3E9.pdf 3.3.2 BLM4P Series (86 Size).7±.3.6±.2 4.5±.2.6±.2 BLM4P Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM4PG6SN 6 (Typ.) 6. 55 to 25 BLM4PG75SN 75 (Typ.) 3.25 55 to 25 BLM4PF8SN 8 (Typ.). 55 to 25 BLM4PG8SN 8 ±25% 3.25 55 to 25 BLM4PG47SN 47 ±25% 2.5 55 to 25 BLM4PG2SN ±25% 5.9 55 to 25 At rated current upper than 5mA, derating is required. Please refer P. 5, "Derating of ated Current". ImpedanceFrequency (Typical) BLM4P Series (88ohm) BLM4P Series (47ohm) 2 2 BLM4AF5SN Impedance (ohm) 5 BLM4AF8SN 9 6 BLM4PG2SN BLM4PG47SN 5 3 ImpedanceFrequency Characteristics BLM4PG6SN BLM4PG75SN 75 75 5 5 25 25 Continued on the following page. 5
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics BLM4PF8SN 4 BLM4PG8SN 75 3 5 25 2 BLM4PG47SN BLM4PG2SN 6 2 45 9 3 5 6 3 Notice (ating) In operating temperatures exceeding +85D, derating of current is necessary for chip Ferrite Beads for which rated current is.5a or over. Please apply the derating curve shown below according to the operating temperature. [Derating] Derated Current [A] 6 5 4 3 2 6A 3A 2A.5A A Operating Temperature [D] 85 25 5
!Note C3E9.pdf 3.3.2 Noise EMI Suppression Effect Effect of BLM_ Series!Waveform Distortion Suppressing Performance of BLM Series [Measuring Circuits] Measuring Point AC4 AC MHz Filter Pattern 2cm Type of Filter EMI Suppression Effect / Description Signal waveform (nsec/div, 2V/div) Expand (nsec/div, 2V/div) Spectrum Initial (No filter) Level [db µv] 85 8 75 7 65 6 55 5 45 3 5 5 2 25 3 Frequency [MHz] inging is caused on the signal waveform. Such ringing contains several hundred MHz harmonic components and generates noise. Signal waveform (nsec/div, 2V/div) Expand (nsec/div, 2V/div) Spectrum esister (47Ω) is used Level [db µv] 85 8 75 7 65 6 55 5 45 3 5 5 2 25 3 Frequency [MHz] Comparing initial waveform, ringing is suppressed a little. However there still remains high level waveform distortion. Signal waveform (nsec/div, 2V/div) Expand (nsec/div, 2V/div) Spectrum BLM8K22SN (22Ω at MHz) is used Level [db µv] 85 8 75 7 65 6 55 5 45 3 5 5 2 25 3 Frequency [MHz] BLM8 has excellent performance for noise suppression and waveform distortion suppression. BLM8 suppresses drastically not only spectrum level in more than MHz range but waveform distortion. 52
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) GHz Noise Suppression Chip Ferrite Beads BLM8H/BLM8E Series BLM8H/BLM8E series has a modified internal electrode structure, that minimizes stray capacitance and increases the effective frequency range. Equivalent Circuit Features (BLM8H series). BLM8H series is realized high impedance at GHz and suitable for noise suppression from 5MHz to GHz range. The impedance value of HG/HDtype is about three times as large as that of A/Btype at GHz, though the impedance characteristic of HG/HDtype is similar to Atype at MHz or less. 2. HGtype is effective in noise suppression in wide frequency range (several MHz to several GHz). HB/HDtype for highspeed signal line provides a sharper rolloff after the cut off frequency. HKtype for digital interface is effective in suppressing the ringing because resistance especially grows in the lower frequency. 3. The magnetic shielded structure minimizes crosstalk. (esistance element becomes dominant at high frequencies.) Features (BLM8E series). Low DC esistance and a large ated Current are suitable for noise suppression of the driver circuit. 2. Excellent direct current characteristics 3. Thin type (t=.5mm) is suitable for small and low profile equipment such as DSC, cellular phones. 53
!Note C3E9.pdf 3.3.2 BLM8H Series (63 Size).4±.2.6±.5.8±.5.8±.5 BLM8H Series (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) Impedance (at GHz, 25 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8HG47SN 47 ±25% 6 (Typ.) 2.85 55 to 25 BLM8HG6SN 6 ±25% 7 (Typ.) 2. 55 to 25 BLM8HG2SN ±25% (Typ.).6 55 to 25 BLM8HB2SN 2 ±25% 5 ±4% 2.5 55 to 25 BLM8HB22SN 22 ±25% ±4%.8 55 to 25 BLM8HB33SN 33 ±25% 6 ±4% 5.2 55 to 25 BLM8HD47SN 47 ±25% (Typ.).2 55 to 25 BLM8HD6SN 6 ±25% 2 (Typ.).5 55 to 25 BLM8HD2SN ±25% 7 (Typ.) 5.8 55 to 25 BLM8HK33SN 33 ±25% 4 ±4% 2.5 55 to 25 BLM8HK47SN 47 ±25% 6 ±4% 2.7 55 to 25 BLM8HK6SN 6 ±25% 7 ±4%.9 55 to 25 BLM8HK2SN ±25% 2 ±4% 5.5 55 to 25 ImpedanceFrequency (Typical) 2 BLM8HG Series 6 BLM8HB Series BLM8HB33SN 5 BLM8HG2SN 2 BLM8HG6SN BLM8HG47SN Impedance (ohm) 8 BLM8HB22SN BLM8HB2SN 5 4 2 2 Continued on the following page. 54
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency (Typical) 4 BLM8HD Series 6 BLM8HK Series 3 2 BLM8HD2SN BLM8HD6SN 2 8 BLM8HK2SN BLM8HK6SN BLM8HK47SN BLM8HK33SN BLM8HD47SN 4 2 2 ImpedanceFrequency Characteristics 8 BLM8HG47SN BLM8HG6SN 6 75 4 5 2 25 2 2 BLM8HG2SN BLM8HB2SN 2 7 6 5 5 Impedance (ohm) 5 4 3 2 2 2 BLM8HB22SN BLM8HB33SN 6 75 2 Impedance (ohm) 5 Impedance (ohm) 8 25 4 2 2 Continued on the following page. 55
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 2 BLM8HD47SN 2 BLM8HD6SN 5 5 5 5 2 Frequency(MHz) 2 Frequency(MHz) BLM8HD2SN BLM8HK33SN 4 6 3 45 2 3 5 2 2 BLM8HK47SN BLM8HK6SN 8 6 75 4 5 2 25 2 2 6 BLM8HK2SN 2 8 4 2 56
!Note C3E9.pdf 3.3.2 BLM8E Series (63 Size).6±.5.8±.5 T.4±.2 BLM8E Series T BLM8EGpppTN BLM8EGpppSN.5±.5.8±.5 (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) Impedance (at GHz, 25 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLM8EGTN ±25% 4 (Typ.) 2.4 55 to 25 BLM8EG2SN 2 ±25% 45 (Typ.) 2.3 55 to 25 BLM8EG39TN 39 ±25% 52 (Typ.) 5.3 55 to 25 BLM8EG6SN 6 ±25% 7 (Typ.) 3.35 55 to 25 At rated current 2mA, derating is required. Please refer P. 5, "Derating of ated Current". ImpedanceFrequency (Typical) 8 Impedance (ohm) 6 4 BLM8EG6SN BLM8EG39TN BLM8EG2SN BLM8EGTN 2 2 ImpedanceFrequency Characteristics BLM8EGTN BLM8EG2SN 6 2 Impedance (ohm) 2 8 4 Impedance (ohm) 6 2 8 4 2 2 Continued on the following page. 57
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics BLM8EG39TN BLM8EG6SN 7 Impedance (ohm) 56 42 28 4 Impedance (ohm) 75 5 25 2 2 58
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect!Noise Suppression in UHF ange [Testing Circuit] 74HCU4 Measured radiation at 3m distance 74AC4 74HC BLM MHz Type of Filter EMI Suppression Effect Description Initial (No filter) Level [dbµv/m] 7 6 5 4 3 2 3 4 5 6 7 8 9 Frequency [MHz] 7 6 Current BLM are effective in suppressing noise in the range between 3MHz and 7MHz. Conventional Type BLM8AG2SN (Ω at MHz) Level [dbµv/m] 5 4 3 Initial 2 3 4 5 6 7 8 9 Frequency [MHz] 7 6 In addition to the effectiveness of current BLM, BLM8HG suppresses noise in the range beyond 7MHz. for GHz Noize Suppression BLM8HG2SN (Ω at MHz) Level [dbµv/m] 5 4 3 Initial BLM8AG2SN 2 3 4 5 6 7 8 9 Frequency [MHz] Comparison between BLM8HG2SN and BLM8AG2SN (CUENT ITEM) 2 Impedance [Ω] 5 5 BLM8HG2SN BLM8AG2SN 2 Frequency [MHz] 59
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Ferrite Beads Arrays BLA2AA/BLA2AB/BLA3A/BLA3B Series BLA2AA/BLA2AB Series Features. BLA2AA/2AB series has 4 circuits in 2.x.mm body with.5mm pitch. 2. Provides attenuation across a broad frequency range. Two types of impedance characteristics are available; one is for general signal line and the other is for high speed signal line. 3. Original inner electrode structure enables extra low crosstalk. 4. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. () (2) (3) (4) (5) (6) (7) (8) 2.±.2.25±.5.5±..2±.5.5±..±.2 : Electrode (in mm) Applications Notebook size PC, PDA and other compact size digital equipment Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLA2AAG2SN4 2 ±25%.5 55 to 25 BLA2AAG22SN4 22 ±25% 5.7 55 to 25 BLA2AAG6SN4 6 ±25% 5. 55 to 25 BLA2AAG2SN4 ±25% 5.3 55 to 25 BLA2ABBSN4 ±25% 2. 55 to 25 BLA2ABB22SN4 22 ±25% 2.2 55 to 25 BLA2ABB47SN4 47 ±25% 2.35 55 to 25 BLA2ABB2SN4 2 ±25% 5.6 55 to 25 BLA2ABB22SN4 22 ±25% 5.9 55 to 25 BLA2ABD47SN4 47 ±25%.65 55 to 25 BLA2ABD6SN4 6 ±25%.8 55 to 25 BLA2ABD2SN4 ±25% 5. 55 to 25 Number of Circuits : 4 Equivalent Circuit ImpedanceFrequency (Typical) BLA2AA Series 2 BLA2AAG2SN4 () (2) (3) (4) 9 BLA2AAG6SN4 Impedance (ohm) 6 BLA2AAG22SN4 (5) (6) (7) (8) 3 BLA2AAG2SN4 No polarity. Continued on the following page. 6
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency (Typical) BLA2ABB Series BLA2ABD Series 6 Impedance (ohm) 8 6 4 BLA2ABB22SN4 Impedance (ohm) 2 8 BLA2ABD2SN4 BLA2ABD6SN4 BLA2ABD47SN4 2 BLA2ABB2SN4 4 ImpedanceFrequency Characteristics 2 BLA2AAG2SN4 4 BLA2AAG22SN4 5 3 Impedance (ohm) Impedance (ohm) 2 5 BLA2AAG6SN4 BLA2AAG2SN4 8 2 Impedance (ohm) 6 4 Impedance (ohm) 9 6 2 3 BLA2ABBSN4 BLA2ABB22SN4 5 4 75 Impedance (ohm) 3 2 Impedance (ohm) 5 25 Continued on the following page. 6
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics BLA2ABB47SN4 BLA2ABB2SN4 2 5 4 Impedance (ohm) Impedance (ohm) 3 2 BLA2ABB22SN4 BLA2ABD47SN4 8 8 6 Impedance (ohm) 6 4 Impedance (ohm) 4 2 2 BLA2ABD6SN4 BLA2ABD2SN4 6 8 2 Impedance (ohm) 6 4 2 Impedance (ohm) 8 4 62
!Note C3E9.pdf 3.3.2 BLA3A/BLA3B Series The miniaturization of electronic equipment requires high performance EMI filters which enable high density mounting. BLA3A/B series consists of 4 circuits of ferrite beads. BLA3A/B is suitable for EMI suppression in smaller digital equipment. () (2) (3) (4) (5) (6) (7) (8).8±.2.3±.2.6±.2 Features. BLA3A/B has 4 circuits in 3.2x.6mm body with.8mm pitch. 2. Provides attenuation across a broad frequency range. Two types of impedance are available which meet general signal line and high speed signal line. 3. Original inner electrode structure enables extra low crosstalk. 4. The nickel barrier structure of the external electrodes provides excellent solder heat resistance. Both flow and reflow soldering methods can be employed..4±.2 3.2±.2.8±. (in mm) Part Number Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) DC esistance (max.) (ohm) Operating Temperature ange ( C) BLA3AG3SN4 3 ±25% 2. 55 to 25 BLA3AG6SN4 6 ±25% 2.5 55 to 25 BLA3AG2SN4 2 ±25% 5.2 55 to 25 BLA3AG22SN4 22 ±25% 5.25 55 to 25 BLA3AG6SN4 6 ±25%.35 55 to 25 BLA3AG2SN4 ±25% 5.45 55 to 25 BLA3BD2SN4 2 ±25% 5.3 55 to 25 BLA3BD22SN4 22 ±25% 5.35 55 to 25 BLA3BD47SN4 47 ±25%.4 55 to 25 BLA3BD6SN4 6 ±25%.45 55 to 25 BLA3BD2SN4 ±25% 5.55 55 to 25 Number of Circuits : 4 Equivalent Circuit () (2) (3) (4) (5) (6) (7) (8) No polarity. 63
!Note C3E9.pdf 3.3.2 ImpedanceFrequency (Typical) BLA3A Series BLA3B Series 2 2 9 BLA3AG2SN4 BLA3AG6SN4 5 6 3 BLA3AG6SN4 BLA3AG22SN4 BLA3AG2SN4 BLA3AG3SN4 5 BLA3BD2SN4 BLA3BD6SN4 BLA3BD47SN4 BLA3BD22SN4 BLA3BD2SN4 ImpedanceFrequency Characteristics 4 BLA3AG3SN4 8 BLA3AG6SN4 3 6 2 4 2 2 BLA3AG2SN4 3 BLA3AG22SN4 5 225 5 5 75 BLA3AG6SN4 BLA3AG2SN4 8 2 6 9 4 6 2 3 64 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 3 BLA3BD2SN4 5 BLA3BD22SN4 225 5 375 25 75 25 8 BLA3BD47SN4 BLA3BD6SN4 6 75 4 5 2 25 2 BLA3BD2SN4 5 5 65
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr Part Numbering Chip EMIFILr Capacitor Type (Global Part Number) NF q M w 3D e CC r 2 t y H u 3 i L o qproduct ID ycharacteristics 2 Product ID NF wstructure Code M Chip EMI Filters Capacitor Type Structure Capacitor Type Code B F U S Capacitance Change ±% +3/8% ±5% 75 ±2ppm/ C +35 to ppm/ C edimensions (LgW) Code 8 2 3D 4 rfeatures Code CC PC Dimensions (LgW).6g.8mm 2.g.25mm 3.2g.25mm 4.5g.6mm EIA 63 85 26 86 Features Capacitor Type for Signal Lines Capacitor Type for Large Current tcapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. uated Voltage Code ated Voltage J 6.3V A V C 6V E 25V H 5V 2A V ielectrode/others Code Electrode 3 Sn Plating opackaging Code Packaging Series L B D Plastic Taping (ø8mm eel) Bulk Paper Taping (ø8mm eel) NFM3D/NFM4 All series NFM8/NFM2 66
!Note C3E9.pdf 3.3.2 Chip EMIFILr Capacitor Array Type (Global Part Number) NF q A w 3 e CC r t S y E u 4 B i o qproduct ID Product ID NF wstructure Code A edimensions (LgW) Code 3 rfeatures Code CC Chip EMI Filters Capacitor Type Structure Array Type Dimensions (LgW) 3.2g.6mm Features Capacitor Type for Signal Lines tcapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. ycharacteristics Code Capacitance Change ±5% S +35 to ppm/ C uated Voltage Code ated Voltage C 6V E 25V inumber of Circuits Code Number of Circuits 4 4 Circuits opackaging Code Packaging B Bulk D Paper Taping (ø8mm eel) 2 67
!Note C3E9.pdf 3.3.2 Chip EMIFILr C Combined Type (Global Part Number) NF q w 2 e GD r 47 t 47 y 2 u L i qproduct ID Product ID NF wstructure Code EMIFILr Structure C Combined Type yesistance Expressed by three figures. The unit is in ohm (Ω). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. uelectrode/others Code Electrode 2 Sn Plating edimensions (LgW) ipackaging 2 Code 2 rfeatures Dimensions (LgW) 2.g.25mm EIA 85 Code L B Packaging Plastic Taping (ø8mm eel) Bulk Code Features GD C Combined Type for Signal Lines tcapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. Chip EMIFILr C Combined Array Type (Global Part Number) NF q A w 3 e GD r t y 4 u D i qproduct ID Product ID NF wstructure Code A edimensions (LgW) Code 3 rfeatures Code GD EMIFILr Structure Array Type Dimensions (LgW) 3.2g.6mm Features C Combined Type for Signal Lines yesistance Expressed by three figures. The unit is in ohm (Ω). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. If there is a decimal point, it is expressed by the capital letter "". In this case, all figures are significant digits. unumber of Circuits Code ipackaging 4 4 Circuits Code B D Number of Circuits Packaging Bulk Paper Taping (ø8mm eel) tcapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. If there is a decimal point, it is expressed by the capital letter "". In this case, all figures are significant digits. 68
!Note C3E9.pdf 3.3.2 Chip EMIFILr LC Combined Type (Global Part Number) NF q W w 3 SP 26 E 4 L e r t y u i o qproduct ID Product ID NF Chip EMI Filters LC Combined Type ycharacteristics (NFL/NFW Series) Code Characteristics Cut off Frequency wstructure Code L W E edimensions (LgW) Code 8 2 3 6 rfeatures Code SP ST PT HT opackaging Structure Monolithic, LC Combined Type Winding, LC Combined Type Block, LC Combined Type Dimensions (LgW).6g.8mm 2.g.25mm 3.2g.6mm 6.8g.6mm Features π Circuit for Signal Lines T Circuit for Signal Lines T Circuit for Large Current T Circuit for Heavyduty EIA 63 85 26 266 tcutoff Frequency (NFL/NFW Series) Expressed by three figures. The unit is in hertz (Hz). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. tcapacitance (NFE Series) Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. ycharacteristics (NFE Series) Code Capacitance Change B ±% C ±2%, ±22% D +2/3%, +22/33% E +2/55%, +22/56% F +3/8%, +22/82% ±5% U 75 ±2ppm/ C Other uated Voltage Code ated Voltage A C E H 2A V 6V 25V 5V V ielectrode Expressed by a figure. Ex.) Code Electrode Series 3 4 9 Sn Plating Solder Coating Others NFL NFW NFE 2 Code Packaging Series K L B D Plastic Taping (ø33mm eel) Plastic Taping (ø8mm eel) Bulk Paper Taping (ø8mm eel) NFW3/NFE NFW3/NFE NFL8/NFL2/NFE NFL8/NFL2 69
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr Capacitor Type NFM8C/NFM2C/NFM3DC/NFM4C Series NFM8C Series The NFM8CC series is a.6x.8mm EMI suppression filter for signal lines which has a 3terminal structure using Murata's multilayer technology..25±..4±..8±..6±. 2 Features. Ultra small size in.6x.8x.6mm enable high density mounting. 2. 3terminal structure with low residual inductance (ESL)* characteristics achieves large insertion loss characteristics even in high frequency area. 3. The NFM8cc series covers capacitance range from 22 to 22pF. NFM8C ().2 min..6±. (2) (2).2±. (3).8±. (in mm) Applications. EMI suppression of circuit for insertion loss in quantity. 2. Noise suppression up to GHz. * Not exceeding onetenth of monolithic ceramic capacitors (2terminal). Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM8CC22UC3 22 +2%,2% 6 3 min. 55 to 25 NFM8CC47UC3 47 +2%,2% 6 3 min. 55 to 25 NFM8CCC3 +2%,2% 6 3 min. 55 to 25 NFM8CC22C3 22 +2%,2% 6 3 min. 55 to 25 NFM8CC47C3 47 +2%,2% 6 3 min. 55 to 25 NFM8CC2C3 +2%,2% 6 3 min. 55 to 25 NFM8CC222C3 22 +2%,2% 6 3 min. 55 to 25 NFM8CC223C3 22 +2%,2% 6 min. 55 to 25 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 2 NFM8CC223C3 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 3 4 5 6 NFM8CC222C3 NFM8CC2C3 NFM8CC47C3 NFM8CC22C3 NFM8CCC3 NFM8CC47UC3 NFM8CC22UC3 7 8 2 7
!Note C3E9.pdf 3.3.2 NFM2C Series.3±.2 The chip "EMIFIL" NFM2C series is a chip type 3terminal EMI suppression filter. It can reduce residual inductance to an extremely low level making it excellent for noise suppression at high frequencies..6±.2.85±. Features. Small and low profile of 2.x.25x.85mm (NFM2C) enables high density mounting. 2. 3terminal structure enables high performance in high frequency range. 3. Uses original electrode structure which realizes excellent solderability. 4. An electrostatic capacitance range of 22 to 22pF enables suppression of noise at specific frequencies. NFM2C 2.±.2 (2) () (3) +.2.2. (2).25±. (in mm) 2 Applications. PCs and peripherals which emit high amount of noise 2. Compact size equipment such as PDA, PC card and mobile telecommunications equipment 3. Severe EMI suppression and high impedance circuits such as digital circuits Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM2CC22UH3 22 +2%,2% 5 3 min. 55 to 25 NFM2CC47UH3 47 +2%,2% 5 3 min. 55 to 25 NFM2CCUH3 +2%,2% 5 3 min. 55 to 25 NFM2CC22H3 22 +2%,2% 5 3 min. 55 to 25 NFM2CC47H3 47 +2%,2% 5 3 min. 55 to 25 NFM2CC2H3 +2%,2% 5 3 min. 55 to 25 NFM2CC222H3 22 +2%,2% 5 3 min. 55 to 25 NFM2CC223H3 22 +2%,2% 5 2 min. 55 to 25 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 2 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 4 6 8 NFM2CC22UH3 NFM2CC47UH3 NFM2CCUH3 NFM2CC22H3 NFM2CC47H3 NFM2CC223H3 NFM2CC222H3 NFM2CC2H3 5 5 5 2 7
!Note C3E9.pdf 3.3.2 NFM3DC Series The chip "EMIFIL" NFM3DC series is a chip type 3terminal EMI suppression filter. It can reduce residual inductance to an extremely low level making it excellent for noise suppression at high frequencies..±.3 3.2±.2.7±.2.25±.2 2 Feature An electrostatic capacitance range of 22 to 22,pF enables suppression of noise at specific frequencies. Application. High noise radiation and high impedance circuits such as digital circuits Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (ma) NFM3DC () Insulation esistance (M ohm).25±.2 (2) (2) (3).3±.2 (in mm) Operating Temperature ange ( C) NFM3DCC22UH3 22 +5%,2% 5 3 min. 55 to 25 NFM3DCC47UH3 47 +5%,2% 5 3 min. 55 to 25 NFM3DCCUH3 +5%,2% 5 3 min. 55 to 25 NFM3DCC22H3 22 +5%,2% 5 3 min. 55 to 25 NFM3DCC47H3 47 +5%,2% 5 3 min. 55 to 25 NFM3DCC2H3 +5%,2% 5 3 min. 55 to 25 NFM3DCC222H3 22 +5%,2% 5 3 min. 55 to 25 NFM3DCC223H3 22 +5%,2% 5 3 min. 55 to 25 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 2 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 4 6 8 NFM3DCC223H3 NFM3DCC222H3 NFM3DCC2H3 NFM3DCC47H3 NFM3DCC22H3 NFM3DCCUH3 NFM3DCC47UH3 NFM3DCC22UH3 5 5 5 2 72
!Note C3E9.pdf 3.3.2 NFM4C Series The chip "EMIFIL" NFM4C series is a chip type 3terminal EMI suppression filter. It can reduce residual inductance to an extremely low level making it excellent for noise suppression at high frequencies..5±.3 4.5±.3.±.2.6±.3 Features An electrostatic capacitance range of 22 to 22,pF enables suppression of noise at specific frequencies. Applications. High noise radiation and high impedance circuits such as digital circuits Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (ma) NFM4C ().3 +.3.2 Insulation esistance (M ohm) (2) (2).4±.3 (3) (in mm) Operating Temperature ange ( C) NFM4CC22U2A3 22 +5%,2% 3 min. 55 to 25 NFM4CC47U2A3 47 +5%,2% 3 min. 55 to 25 NFM4CCU2A3 +5%,2% 3 min. 55 to 25 NFM4CC22U2A3 22 +5%,2% 3 min. 55 to 25 NFM4CC472A3 47 +5%,2% 3 min. 55 to 25 NFM4CC22A3 +5%,2% 3 min. 55 to 25 NFM4CC2222A3 22 +5%,2% 3 min. 55 to 25 NFM4CC2232A3 22 +5%,2% 3 min. 55 to 25 2 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 2 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 4 6 8 NFM4CC2232A3 NFM4CC2222A3 NFM4CC22A3 NFM4CC472A3 NFM4CC22U2A3 NFM4CCU2A3 NFM4CC47U2A3 NFM4CC22U2A3 5 5 5 2 73
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr Capacitor Array Type NFA3C Series The NFA3C series is a chip EMI suppression filter for surface mount applications by using Murata's ceramic processing technology and filter design technology. The series is well suited for EMI suppression in digital I/O lines of varied electronic equipment such as notebook size PCs. () 3.2±.2.8±..6±.2 (7) (8) (9) ().4±.2.±.5 (2).8±.2 2 Features. High density mounting can be realized because of 4 circuits in one package with.8mm pitch. 2. Suitable for high frequency noise suppression because of low residual inductance of 3terminal structure. 3. Excellent EMI suppression can be realized because of 2terminal simple GNDs for 4 circuits. 4. 2 to 22,pF lineups can be used depending on noise frequency. (3) (4) (5) (6).5 min..5 min. (in mm) Applications. Personal computers and peripherals 2. Telephones, PPCs, communications equipment 3. Digital TVs, VCs Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFA3CC22SE4 22 +2%,2% 25 2 min. 4 to 85 NFA3CC47SE4 47 +2%,2% 25 2 min. 4 to 85 NFA3CCSE4 +2%,2% 25 2 min. 4 to 85 NFA3CC22SE4 22 +2%,2% 25 2 min. 4 to 85 NFA3CC47E4 47 +2%,2% 25 2 min. 4 to 85 NFA3CC2E4 +2%,2% 25 2 min. 4 to 85 NFA3CC222E4 22 +2%,2% 25 2 min. 4 to 85 NFA3CC223C4 22 +2%,2% 6 2 min. 4 to 85 Number of Circuits : 4 Equivalent Circuit Insertion Loss Characteristics (Typical) Input (7) (8) (9) () (5Ω 5Ω) NFA3CC47SE4 NFA3CC22SE4 2 GND () (3) (4) (5) (6) (2) GND Insertion Loss (db) 4 6 8 NFA3CC223C4 NFA3CC222E4 NFA3CC2E4 NFA3CC47E4 NFA3CC22SE4 NFA3CCSE4 Output No polarity. 5 5 5 2 74
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr C Combined Type NF2G Series The NF2G series comprises high performance EMI suppression filters which can suppress distortion of waveform. Various items may be used, considering circuit impedance and noise condition. (Top View). max..±.35.5±.2.95±.35 Features. Murata's original inner design realizes small and low profile of 2.x.25x.5mm. 2. Distributed constant circuit realizes smooth change of impedance which prevents reflection of signal and distortion of wave shape. 3. The NF2G series is effective in a line where ground is not stable, because the resistance element in the filter absorbs noise and returns it to ground line. 4. The NF2G series has no polarity so it can be used in dual direction transport lines. 5. The NF2G series has various lineups of resistance (22 to ohm) and capacitance ( to pf). (Bottom View) ().3±.2.25 2.±.2 (2) (2) (3).3±.2.25.25±.2 (in mm) 2 Applications Interface lines and clock lines where signals are tend to be distorted Part Number Capacitance (pf) esistance (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Operating Temperature ange ( C) NF2GD222 +2%,2% 22 +3%,3% 5 5 min. 4 to 85 NF2GD472 +2%,2% 47 +3%,3% 35 5 min. 4 to 85 NF2GD47222 47 +2%,2% 22 +3%,3% 5 5 min. 4 to 85 NF2GD47472 47 +2%,2% 47 +3%,3% 35 5 min. 4 to 85 NF2GD47682 47 +2%,2% 68 +3%,3% 3 5 min. 4 to 85 NF2GD472 47 +2%,2% +3%,3% 25 5 min. 4 to 85 NF2GD222 +2%,2% 22 +3%,3% 5 5 min. 4 to 85 NF2GD472 +2%,2% 47 +3%,3% 35 5 min. 4 to 85 NF2GD682 +2%,2% 68 +3%,3% 3 5 min. 4 to 85 NF2GD2 +2%,2% +3%,3% 25 5 min. 4 to 85 Number of Circuits : 75
!Note C3E9.pdf 3.3.2 Equivalent Circuit () Input Output (3) GND (2) No polarity 2 Insertion Loss Characteristics (Typical) (5Ω 5Ω) (5Ω 3kΩ) NF2GD472 Insertion Loss (db) 2 3 4 NF2GD222 NF2GD472 NF2GD47222 NF2GD47472 NF2GD47682 NF2GD222 NF2GD472 NF2GD682 Insertion Loss (db) 2 3 4 NF2GD2 5 5 76
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect of NF2G Series!Effect of Noise Suppression by NF2G The NF2G is effective even if ground line is not stable [Testing Circuit] enough due to its distributed constant circuit structure. HCU4 HC4 Filter HC 5cm Signal Pattern MHz With Stable Ground Line Type of Filter EMI Suppression Effect Description Noise Level without Filter Noise Level [db µ V/m] 6 5 4 3 2 3 84 38 92 Frequency [MHz] 246 3 Filter Signal line Ground pattern Thruhole (connection ground pattern with ground plane) Whole surface (back side) ground plane 2 Filter Mounting Condition Standard Type Chip EMIFILr (pf) Noise Level [db µ V/m] 6 5 4 3 2 The standard type chip EMIFILr is effective on stable ground lines. 3 84 38 92 Frequency [MHz] 246 3 Filter Mounting Condition NF2GD472 Noise Level [db µ V/m] 6 5 4 3 2 The NF2G has some advantages to standard type EMIFILr on stable ground lines. 3 84 38 92 Frequency [MHz] 246 3 With Poor Ground Line Type of Filter EMI Suppression Effect Description Noise Level without Filter Noise Level [db µ V/m] 6 5 4 3 2 Filter Signal line Ground pattern 3 84 38 92 Frequency [MHz] 246 3 Without ground plane Filter Mounting Condition Standard Type Chip EMIFILr (pf) Noise Level [db µ V/m] 6 5 4 3 2 The standard type EMIFILr loses efficiency on poor ground lines. 3 84 38 92 Frequency [MHz] 246 3 Filter Mounting Condition NF2GD472 Noise Level [db µ V/m] 6 5 4 3 2 The NF2G is effective even on poor ground lines because of its distributed constant circuit structure and unique system to limit rush current. 3 84 38 92 Frequency [MHz] 246 3 77
!Note C3E9.pdf 3.3.2 Noise EMI Suppression Effect Effect of NF2G Series!Waveform Distortion Suppressing Function by NF2G [Testing Circuit] HCU4 AC4 Filter AC4 Measuring Point MHz Type of Filter EMI Suppression Effect Description 2 Voltage Waveform esonance between the internal capacitance of the IC and the inductance of the print pattern causes waveform overshooting and undershooting. Initial Waveform (no filter) :V/div :2ns/div Voltage Waveform Ordinary capacitor filters have no waveform distortion suppressing capability, and they cannot suppress disturbances in the waveforms. When Ordinary Capacitor Filter is Used :V/div :2ns/div Voltage Waveform The waveform distortion suppressing function of the NF2G minimizes disturbances of waveforms. NF2G :V/div :2ns/div 78
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr C Combined Array Type NFA3G Series NFA3G series is a high performance EMI suppression filter array with a 4circuit noise filter in 3.2x.6mm size. NFA3G realizes high density mounting. (Top View) (7) (8) (9) () () (2) (3) (4) (5) (6) Features. NFA3G is a 4circuit noise filter in 3.2x.6mm size with.8mm pitch. High density mounting is available. 2. 3terminal structure enables excellent high frequency performance. 3. Distributed constant circuit realizes smooth change of impedance which prevents reflection of signal and distortion of wave shape. 4. NFA3G series is effective in lines where ground is not stable, because the resistance element in the filter absorbs noise and returns it to ground line..4±.5.8±. 3.2±.2 (Bottom View).5 min..8±.2.5 min..±.5.6±.2 (in mm) 2 Part Number Capacitance (pf) esistance (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Operating Temperature ange ( C) NFA3GD684 +2%,2% 6.8 +4%,4% 5 6 min 4 to 85 NFA3GD474 +2%,2% 47 +3%,3% 2 6 min 4 to 85 NFA3GD4 +2%,2% +3%,3% 5 6 min 4 to 85 NFA3GD47684 47 +2%,2% 6.8 +4%,4% 5 6 min 4 to 85 NFA3GD47474 47 +2%,2% 47 +3%,3% 2 6 min 4 to 85 NFA3GD474 47 +2%,2% +3%,3% 5 6 min 4 to 85 NFA3GD684 +2%,2% 6.8 +4%,4% 5 6 min 4 to 85 NFA3GD474 +2%,2% 47 +3%,3% 2 6 min 4 to 85 NFA3GD4 +2%,2% +3%,3% 5 6 min 4 to 85 Number of Circuits : 4 Equivalent Circuit Input (7) (8) (9) () ()GND (2)GND (3) (4) (5) (6) Output No polarity 79
!Note C3E9.pdf 3.3.2 Insertion Loss Characteristics (5Ω 5Ω) (5Ω 5Ω) NFA3GD684 NFA3GD474 Insertion Loss (db) 2 3 NFA3GD47684 NFA3GD684 Insertion Loss (db) 2 3 NFA3GD47474 NFA3GD474 4 4 5 2 5 2 2 (5Ω 5Ω) Insertion Loss (db) 2 3 4 NFA3GD4 NFA3GD474 NFA3GD4 5 2 8
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr LC Combined Monolithic Type NFL8ST/NFL8SP/NFL2S Series NFL8ST Series Ths NFL8ST series is an EMI suppression filter for high speed signal lines, achieving Ttype structure in.6x.8mm size with Murata's multilayer technology..2 min..2 min. (2) () (3).8±. Features. Ultrasmall size in.6x.8x.8mm 2. Steep insertion loss characteristics realize excellent noise suppression and prevent distortion of signal waveform. 3. By minimizing stray capacitance of inductor, achieves high performance in noise suppression in high frequency range. 4. Five different values of cutoff frequency are available, ranging from MHz up to 5MHz. 5. No polarity using the same structure on all the side electrodes..25±. (2).25±..4±..6±..8±. (in mm) 2 Applications Noise suppression for video signal lines (GB lines) and high speed clock lines Part Number Cutoff Frequency (MHz) Capacitance (pf) Inductance (nh) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFL8ST7C3 4 +2%,2% 75 +2%,2% 6 min. 55 to 25 NFL8ST57C3 5 32 +2%,2% 4 +2%,2% 6 min. 55 to 25 NFL8ST27C3 2 25 +2%,2% +2%,2% 6 5 min. 55 to 25 NFL8ST37C3 3 8 +2%,2% 62 +2%,2% 6 2 min. 55 to 25 NFL8ST57C3 5 +2%,2% 43 +2%,2% 6 2 min. 55 to 25 Number of Circuits : Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) Input () GND (2) Output (3) Insertion Loss (db) 2 4 6 NFL8ST57C3 NFL8ST37C3 NFL8ST27C3 NFL8ST57C3 NFL8ST7C3 No Polarity 8 5 5 5 5 8
!Note C3E9.pdf 3.3.2 NFL8SP Series The chip "EMIFIL" NFL8SP series is an EMI suppression filter for high speed signal lines, achieving pitype structure in 63 size with Murata's multilayer technology..6±..5±..8±. 2 Features. Ultrasmall size in.6x.8x.6 mm 2. Achieves high performance in noise suppression over wide frequency range. 3. Steep insertion loss characteristics realize excellent noise suppression and prevent distortion of signal waveform. 4. Line up 4 items of cutoff frequency range from 5 to 5MHz..2 min..3±..4±..3±..5±..5±..6±. (in mm) Applications EMI suppression for digital signal line such as GB and high speed clock lines Part Number Cutoff Frequency (MHz) Capacitance (pf) Inductance (nh) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFL8SP57A3 5 34 +2%,2% +2%,2% min. 55 to 25 NFL8SP27A3 2 24 +2%,2% 8 +2%,2% min. 55 to 25 NFL8SP37A3 3 9 +2%,2% 6 +2%,2% min. 55 to 25 NFL8SP57A3 5 +2%,2% 38 +2%,2% min. 55 to 25 Number of Circuits : Equivalent Circuit Insertion Loss Characteristics (Typical) 55Ω NFL8SP57A3 () Input Output (3) GND (2) Insertion Loss (db) 2 3 4 5 NFL8SP27A3 NFL8SP37A3 NFL8SP57A3 6 No polarity. 7 2 82
!Note C3E9.pdf 3.3.2 NFL2S Series.3±.2 The chip "EMIFIL" NFL2S series is a high performance EMI suppression filter in 2.x.25mm size for high speed signal lines by using Murata's processing technology..6±.2.85±. 2.±.2 Features. Suppresses noise with few effects on the signal itself due to its steep filtering characteristics. 2. Murata's original internal structure design enables excellent noise suppression up to high frequencies. 3. Available in nine different values of cutoff frequency ranging from 2MHz up to 5MHz. Applications Suppression of high magnitude radiated noise generated by high speed digital circuits such as clock and GB () (2).5 min. (2) (3).25±. (in mm) 2 Part Number Cutoff Frequency (MHz) Capacitance (pf) Inductance (nh) ated Voltage (Vdc) ated Current (ma) Insulation esistance (M ohm) Operating Temperature ange ( C) NFL2SP26C3 2 24 +2%,2% 7 +2%,2% 6 min. 55 to 25 NFL2SP56C3 5 84 +2%,2% 35 +2%,2% 6 5 min. 55 to 25 NFL2SP76C3 7 76 +2%,2% 85 +2%,2% 6 5 min. 55 to 25 NFL2SP7C3 44 +2%,2% 35 +2%,2% 6 2 min. 55 to 25 NFL2SP57C3 5 28 +2%,2% 28 +2%,2% 6 2 min. 55 to 25 NFL2SP27C3 2 22 +2%,2% 72 +2%,2% 6 25 min. 55 to 25 NFL2SP37C3 3 9 +%,% 45 +%,% 6 3 min. 55 to 25 NFL2SP47C3 4 6 +%,% 34 +%,% 6 3 min. 55 to 25 NFL2SP57C3 5 2 +%,% 3 +%,% 6 3 min. 55 to 25 Number of Circuits : Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) NFL2SP57C3 () Input Output (3) GND (2) Insertion Loss (db) 2 4 6 NFL2SP47C3 NFL2SP37C3 NFL2SP27C3 NFL2SP57C3 NFL2SP7C3 NFL2SP76C3 NFL2SP56C3 NFL2SP26C3 No polarity. 8 5 5 5 2 83
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr LC Combined Winding Type NFW3S Series 2 The signal line chip EMI filter NFW3S series consists of high performance EMI suppression filters. They are designed for noise suppression in high speed signal digital circuits in which the signal harmonics are prone to becoming noise sources. These filters achieve a db/dec. (typ.) damping characteristic with Murata's innovative circuit design. This makes these chips effective in applications where the signal and noise frequencies are close to each other. Features. Suppresses signal noise with little or no attenuation of the signal itself. 2. Murata's original internal structure design enables excellent noise suppression up to high frequencies (4dB at GHz typ.). 3. The NFW3S series is available in six different values of cutoff frequency ranging from MHz up to 5MHz. 2.3±.2 3.2±.3 () (2) (3).7±.3.7±.3.65±.2.6±.2.8±.2 () : Input electrode (2) : Ground electrode (3) : Output electrode No polarity. (in mm) Part Number Nominal Cutoff Freq. (MHz) Attenuation at MHz (db) Attenuation at 2MHz (db) Attenuation at 5MHz (db) Attenuation at MHz (db) Attenuation at 5MHz (db) Attenuation at 2MHz (db) Attenuation at 3MHz (db) Attenuation at 4MHz (db) Attenuation at 5MHz (db) Attenuation at MHz (db) NFW3SP6E4 6 max. 5 min. 25 min. 25 min. 25 min. 3 min. 3 min. NFW3SP26E4 2 6 max. 5 min. 25 min. 25 min. 3 min. 3 min. NFW3SP56E4 5 6 max. min. 3 min. 3 min. 3 min. NFW3SP7E4 6 max. 5 min. 2 min. 3 min. NFW3SP57E4 5 6 max. min. 2 min 3 min. 3 min. NFW3SP27E4 2 6 max. min. 3 min. NFW3SP37E4 3 6 max. 5 min. 5 min. NFW3SP47E4 4 6 max. min. NFW3SP57E4 5 6 max. min. ated Current : 2mA ated Voltage : 25Vdc Operating Temperature ange : 4 C to 85 C Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) () Input Output (3) GND (2) No polarity. Insertion Loss (db) 2 4 6 NFW3SP57E4 NFW3SP27E4 NFW3SP37E4 NFW3SP47E4 NFW3SP57E4 NFW3SP6E4 NFW3SP26E4 NFW3SP56E4 NFW3SP7E4 8 5 5 5 2 84
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect of NFW3S Series!Example of EMI Suppression in an Actual Circuit [Measuring Circuit] 74ALS4 EMI Suppression Filter Measuring Point 74ALS MHz Type of Filter Signal Wave Form ( 2ns/div v/div ) EMI Suppression Effect Description Signal Waveform and Noise Spectrum before Filter Mounting Signal Waveform 2ns/div ( V/div) Noise Spectrum (: Active Probe) Noise Level [dbµv] 8 6 4 2 2 3 4 5 Frequency [MHz] 2 NFW3S Series (Cutoff frequency 5MHz) Noise Level [dbµv] 8 6 4 2 Level before filter mounting The NFW3S's steep attenuation characteristic means excellent EMI suppression without waveform cornering. 2 3 4 5 Frequency [MHz] Conventional Chip Solid type EMI Filter (NFM4CC 47pF) Noise Level [dbµv] 8 6 4 2 Level before filter mounting 3terminal capacitors suppress signal frequencies as EMI frequencies so the signal waveform is distorted. 2 3 4 5 Frequency [MHz] Filter Combined with Conventional LCs L C L Noise Level [dbµv] 8 6 4 2 Level before filter mounting Combinations of inductors and capacitors can yield a steep attenuation characteristic, but they require a great deal more mounting space. Moreover, at high frequencies the EMI suppression is less than that obtained by the NFW3S. L : Chip Inductor C : Chip Capacitor (27pF) 2 3 4 5 Frequency [MHz] 85
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr LC Combined Type for Large Current NFE3P/NFE6P/NFE6H Series NFE3P Series 2 The chip "EMIFIL" NFE3P is a small size Ttype circuit EMI suppression filter. Features. Its large rated current of 6A and low voltage drop due to small DC resistance are suitable for DC power line use. 2. The feedthrough capacitor realizes excellent high frequency characteristics. 3. The structure incorporates builtin ferrite beads which minimize resonance with surrounding circuits. 4. 22 to 22,pF lineups can be used for signal lines..7±.2.±.2.7±.2 () (2) (3).6±.2 3.2±.4.6±.2 (in mm) Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFE3PT22E9 22 +3%,3% 25 6 min. 4 to 85 NFE3PT47CE9 47 +5%,2% 25 6 min. 4 to 85 NFE3PTCE9 +8%,2% 25 6 min. 4 to 85 NFE3PT22DE9 22 +5%,2% 25 6 min. 4 to 85 NFE3PT47FE9 47 +5%,2% 25 6 min. 4 to 85 NFE3PT52E9 5 +5%,2% 25 6 min. 4 to 85 NFE3PT222E9 22 +5%,5% 25 6 min. 4 to 85 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) NFE3PT22E9 NFE3PT47CE9 Input Output () (3) GND (2) Insertion Loss (db) 2 3 4 NFE3PTCE9 NFE3PT22DE9 NFE3PT47FE9 NFE3PT52E9 NFE3PT222E9 No polarity. 5 2 86
!Note C3E9.pdf 3.3.2 NFE6P Series The chip "EMIFIL" NFE6P is a Ttype circuit EMI suppression filter..7±.2 2.6±.3.7±.2 Feature. Its large rated current of 2A and low voltage drop due to small DC resistance are suitable for DC power line use. 2. The feedthrough capacitor realizes excellent high frequency characteristics. 3. The structure incorporates builtin ferrite beads which minimize resonance with surrounding circuits. 4. 33 to 4,7pF lineups can be used for signal lines. Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) () (2) (3) 6.8±.5.6±.3.6±.3 (in mm) Operating Temperature ange ( C) NFE6PT33BH9 33 +3%,3% 5 2 min. 25 to 85 NFE6PT68BH9 68 +3%,3% 5 2 min. 25 to 85 NFE6PTH9 +3%,3% 5 2 min. 25 to 85 NFE6PT8BH9 8 +3%,3% 5 2 min. 25 to 85 NFE6PT36BH9 36 +2%,2% 5 2 min. 25 to 85 NFE6PT68BH9 68 +3%,3% 5 2 min. 25 to 85 NFE6PT2EH9 +8%,2% 5 2 min. 25 to 85 NFE6PT472CH9 47 +8%,2% 5 2 min. 25 to 85 2 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) NFE6PT33BH9 NFE6PT68BH9 NFE6PTH9 Input Output () (3) GND (2) Insertion Loss (db) 2 3 4 5 NFE6PT8BH9 NFE6PT36BH9 NFE6PT68BH9 NFE6PT2EH9 NFE6PT472CH9 No polarity. 6. 87
!Note C3E9.pdf 3.3.2 NFE6H Series The Ttype chip EMI Filter NFE6H series consists of a feedthrough capacitor and ferrite beads. Extending the operating conditions of NFE6P, NFE6H series can be used in an application set under severe operating conditions..7±.2 2.6±.3.7±.2 () (2) (3).6±.3 2 Features. These filters have an extended operating temperature range of 55 to +25 degree C. 2. Its large rated current of 2A and low voltage drop due to small DC resistance are suitable for DC power line use. 3. The feedthrough capacitor realizes excellent high frequency characteristics. 4. The structure incorporates builtin ferrite beads which minimize resonance with surrounding circuits. 5. 33 to 3,3pF lineups can be used for signal lines. 6.8 +.3.5.6±.3 (in mm) Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFE6HT33U2A9 33 +3%,3% 2 min. 55 to 25 NFE6HT682A9 68 +3%,3% 2 min. 55 to 25 NFE6HT2A9 +3%,3% 2 min. 55 to 25 NFE6HT8C2A9 8 +3%,3% 2 min. 55 to 25 NFE6HT36C2A9 36 +2%,2% 2 min. 55 to 25 NFE6HT68D2A9 68 +3%,3% 2 min. 55 to 25 NFE6HT2F2A9 +8%,2% 2 min. 55 to 25 NFE6HT3322A9 33 +8%,2% 2 min. 55 to 25 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) NFE6HT33U2A9 NFE6HT682A9 NFE6HT2A9 Input Output () (3) Insertion Loss (db) 2 3 4 NFE6HT8C2A9 NFE6HT36C2A9 NFE6HT68D2A9 NFE6HT2F2A9 NFE6HT3322A9 GND (2) 5 No polarity. 6. 88
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIFILr for Large Current NFM8P/2P/3DP/4P Series NFM8P Series The NFM8P series is an EMI suppression filter for high speed IC power lines which realizes large capacitance microf max. and rated current 2A in 68 size by Murata's multilayer technology. Features. Ultrasmall size in.6x.8mm. 2. 3terminal structure with low residual (ESL)* and large capacitance microf (max.) realize large insertion loss characteristics over wide frequency range. 3. Large rated current 2A is suitable for noise suppression of circuits which require large current. 4. The NFM8P series has line up of capacitance. to. microf. * Not exceeding onetenth of monolithic ceramic capacitors (2terminal). Applications. Noise suppression for large capacitance circuits such as high speed IC power lines 2. Control change of voltage for high speed IC.2 min..2 min. (2) () (3).25±. (2).25±..4±..8±..6±. NFM8P ( micro F) (in mm).25±..4±..8±..2 min..6±. (2) () (3).8±..6±. NFM8P (..47 micro F) (2).2±. (in mm).8±. 2 Part Number Capacitance (µf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM8PC4C3. +2%,2% 6 2 min. 55 to 25 NFM8PC224J3.22 +2%,2% 6.3 2 min. 55 to 25 NFM8PC474J3.47 +2%,2% 6.3 2 min. 55 to 25 NFM8PC5J3. +2%,2% 6.3 2 5 min. 55 to 5 Equivalent Circuit Insertion Loss Characteristics NFM8P Series (5Ω 5Ω) () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 2 3 4 5 6 7 8 NFM8PC4C3 NFM8PC224J3 NFM8PC474J3 NFM8PC5J3 9. 2 89
!Note C3E9.pdf 3.3.2 NFM2P Series.3±.2 NFM2P is a 3terminal structure component. This product can be applied to large current DC power lines. NFM2P is suitable for noise suppression of DC power lines where relatively operates large current..6±.2.85±. 2 Features. The rated current of 4A is suitable for IC's individual power lines. 2. Small dimension enables higher density packaging. NFM2P is much smaller size (2.x.25x.85mm). 3. Murata's original internal electrode structure design realizes excellent EMI suppression effects from low frequency to high frequency. NFM2P 2.±.2 (2) () (3) (2).25±.2.25±. (in mm) Part Number Capacitance (µf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM2PC4E3. +2%,2% 25 2 min. 55 to 25 NFM2PC224C3.22 +2%,2% 6 2 min. 55 to 25 NFM2PC474C3.47 +2%,2% 6 2 min. 55 to 25 NFM2PC5BA3. +2%,2% 4 5 min. 4 to 85 NFM2PC5FC3. +8%,2% 6 2 5 min. 4 to 85 Equivalent Circuit Insertion Loss Characteristics NFM2P Series (5Ω 5Ω) 2 NFM2PC4E3 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) NFM2PC224C3 4 6 NFM2PC474C3 8 NFM2PC5FC3 NFM2PC5BA3 2 9
!Note C3E9.pdf 3.3.2 NFM3DP Series The chip "EMIFIL" NFM3DP is a chip type 3terminal capacitor with high rated current of 2A. This series is suited for noise suppression in DC power supply lines of digital instruments..±.3 3.2±.2.7±.2.25±.2 Features. Large rated current (2A) is suitable for application in DC power lines. 2. Small size (3.2x.25mm) and low profile (.7mm max.) NFM3DP ().25±.2 (2) (2) (3).3±.2 (in mm) Applications. Personal computers, word processors and peripherals 2. Telephones, PPCs, communications equipment, etc. 3. Digital TVs, VCs 4. Telecommunications equipment 2 Part Number Capacitance (µf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM3DPC223H3.22 +2%,2% 5 2 min. 55 to 85 Equivalent Circuit Insertion Loss Characteristics NFM3DP (5Ω 5Ω) 2 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 4 6 8..5 5 5 5 Notice (ating) When the NFM3DP series is used in operating temperatures exceeding +85 C, derating of current is necessary. Please apply the derating curve shown below according to the operating temperature. ated Current (A) 2..5 55 Operating Temperature ( C) 85 25 9
!Note C3E9.pdf 3.3.2 NFM4P Series The chip "EMIFIL" NFM4P series consists of 3terminal structure SMT components. These components are able to be applied to large current DC power lines. NFM4P series are suitable in noise suppression in DC lines where relatively large currents operate..5±.3 4.5±.3 (2).±.2.6±.3 2 Features. Large rated current (2A) is suitable for the application in DC power lines. 2. High electrostatic capacitance and remarkable high frequency performance are effective for immunity against surge noise and pulse noise. Applications. Personal computers, word processors and peripherals 2. Telephones, PPCs, communications equipment, etc. 3. Digital TVs, VCs 4. Telecommunications equipment NFM4P () (3).3±.3.2 (2).4±.3 (in mm) Part Number Capacitance (µf) ated Voltage (Vdc) ated Current (A) Insulation esistance (M ohm) Operating Temperature ange ( C) NFM4PC24FH3.2 +8%,2% 5 2 min. 55 to 85 Equivalent Circuit Insertion Loss Characteristics NFM4P (5Ω 5Ω) 2 () Input Output (3) GND (2) * no polarity. Insertion Loss (db) 4 6 8 5 5 5 92
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIGUADr (EMIFILr with Varistor Function) Part Numbering Chip EMIGUADr (EMIFILr with Varistor Function) (Global Part Number) VF q M w 4 N 222 N C L e r t y u i o qproduct ID Product ID VF wstructure Code M Chip EMIGUADr Structure Monolithic Type ycapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. ucapacitance Tolerance Code Capacitance Tolerance N ±3% edimensions (LgW) iated Voltage Code 4 Dimensions (LgW) 4.5g.6mm EIA 86 Code C ated Voltage 6V 3 router Electrode opackaging Code Outer Electrode Code Packaging Standard Type L Plastic Taping (ø8mm eel) tcategory B Bulk Code Category N Standard 93
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip EMIGUADr (EMIFILr with Varistor Function) VFM4 Series Features The VFM4 series is a chip type EMI filter with varistor function. Its 3terminal structure provides high performance by suppressing high frequency noise and absorbing surge noise. VFM4 can meet both EMI noise and surge noise..4±.3.4±.3.4±.3 (2) () (3) (2) 4.5±.3.25±.3 Applications ESD surge protection and EMI suppression in various electric equipment such as car electronic equipment, portable electronic equipment, telecommunication terminals, office automation equipment, home automation equipment or factory automation equipment.6±.3 in mm 3 Part Number ated Voltage (Vdc) Varistor Voltage (V) Clumping Voltage (max.) Capacitance (pf) ated Current (ma) Peak Pulse Current (A) Operating Temperature ange ( C) VFM4N222NC 6 27 +5V,5V 5V(V2A) 22 +3%,3% 2 5 4 to 25 Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (5Ω 5Ω) () Input GND (2) Output (3) Insertion Loss (db) 2 4 6 No polarity 8 5 5 5 94
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect of VFM Series!Impulse Noise Absorption (Comparison between VFM4 and Standard 2terminal Varistor) [TESTING CICUIT] Oscilloscope Sample 5Ω Attenuator Impulse Generator (o=5ω) (Pulse Width ns) Type of Filter EMI Suppression Effect Description Original Waveform Voltage Waveform Frequency Spectrum Output Voltage [V] Output Voltage [dbm] 2225 675 25 575 25 5 5 5 2 Time [ns] 3 2 2 MHz Frequency [LINEA] 99MHz The Lower chart is a frequency response of the upper chart. Note that the scale of original wave chart and that of the output wave chart is different because of circumstances. 3 The commonly used 2terminal varistor Final voltage falls below V because of the effect of signal reflection. Voltage Waveform Frequency Spectrum Output Voltage [V] Output Voltage [dbm] 3 2 74V peak 5 5 5 2 Time [ns] 3 2 2 MHz Frequency [LINEA] 99MHz The rising part of pulse, which is mostly consists of highfrequency element, remains because inductance in electrodes becomes obstacle. Chip Solid EMIGUAD r VFM4 Voltage Waveform Output Voltage [V] 3 2 76V peak 5 5 5 2 Time [ns] The 3terminal structure minimizes the effect of inductance in electrodes and pulse rising noise is absorbed completely. Frequency Spectrum Output Voltage [dbm] 3 2 2 MHz Frequency [LINEA] 99MHz 95
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Part Numbering Chip Common Mode Choke Coils (Global Part Number) DL q W w 2 S N 37 S Q 2 L e r t y u i o! qproduct ID tcategory Product ID Code Category DL Chip Common Mode Choke Coils N Standard Type 4 wstructure Code Structure W Winding Type M Monolithic Type P Film Type edimensions (LgW) Code Dimensions (LgW) EIA 2 3 2H 5A 5B.25g.mm 2.g.2mm 3.2g.6mm 2.5g2.mm 5.g3.6mm 5.g5.mm 54 85 26 8 24 22 rtype Code Type S Magnetically Shielded One Circuit Type D Magnetically Shielded Two Circuit Type H Open Magnetic One Circuit Type G Magnetically Monolithic Type (sectional winding) yimpedance Typical impedance at MHz is expressed by three figures. The unit is in ohm (Ω). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. ucircuit Ex.) ifeatures Code L Q Code 2 3 4 Code S M onumber of Signal Line Circuit Standard Type Features Expressed by a letter. Number of Signal Line Two Lines Three Lines Four Lines Series except DLP3D DLP3D!Packaging Code Packaging Series K L B Plastic Taping (ø33mm eel) Plastic Taping (ø8mm eel) Bulk DLW5AH/DLW5BS All series All series 96
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Film Type DLPS/DLP3S Series DLPS Series.3±. Features. Small size and tight dimensional tolerance SIE :.25x.x.82mm tolerance : +/.mm 2. Useful impedance lineup 9/2/6/2ohm 3. High noise suppression for high frequency 4. No distortion to highspeed signal transmission Applications Common mode noise suppression of high speed differential signal lines for USB, IEEE394, LVDS.. Note PC, PDA 2. Cellular phone 3. Digital Still Camera, Digital Video Camera (4) (3).55±. ().±. (2).25 +..5.25±..82±. (in mm) Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLPSN9SL2 9 ±2% 6 5 min. 2.5.4 ±25% DLPSN2SL2 2 ±2% 4 5 min. 2.5 2. ±25% DLPSN6SL2 6 ±2% 2 5 min. 2.5 2.7 ±25% DLPSN2SL2 2 ±2% 3 5 min. 2.5 2.5 ±25% Operating Temperature ange : 4 C to 85 C Equivalent Circuit ImpedanceFrequency Characteristics 4 () (2) Common mode DLPSN2SL2 DLPSN6SL2 DLPSN2SL2 DLPSN9SL2 DLPSN9SL2 DLPSN2SL2 (4) (3) No polarity DLPSN2SL2 DLPSN6SL2 Differential mode 97
!Note C3E9.pdf 3.3.2 DLP3S Series DLP3S series is chip common mode choke coil that realizes high impedance in a small size with ferrite material technology and film processing technology. DLP3S series has excellent performance at high frequency range. It is suitable for differential signal line application. Features. Small size, low profile, SMD. 3.2x.6x.5mm (tolerance:.5mm) 2. High common mode impedance (55ohm at MHz typ.) in small size. 3. DLP3S suppresses high frequency noise that was unable to be suppresses with existing common mode choke coils. Suitable for differential signal lines as like USB, because DLP3S does not provide distortion to high speed signal transmission due to its high coupling (coupling coefficient:.98 min.) Applications. USB lines of PC, peripheral equipment. 2. LVDS lines of NotePC, LCD. 3. USB lines of digital AV equipment such as digital cameras. (4) () (3) (2) (2.).7±.2 3.2±.5.3±.2.5±.5.6±.5 (in mm) 4 Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLP3SN2SL2 2 ±2% 6 min. 4 2. max. DLP3SN22SL2 22 ±2% 6 min. 4 2.5 max. DLP3SN55SL2 55 ±2% 6 min. 4 3.6 max. Operating Temperature ange : 4 C to 85 C Equivalent Circuit ImpedanceFrequency Characteristics () (2) (Common mode) DLP3SN55SL2 DLP3SN22SL2 DLP3SN2SL2 (4) (3) No polarity DLP3SN2SL2 DLP3SN22SL2 (Differential mode) DLP3SN55SL2 98
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Arrays Film Type DLP3D Series DLP3D Series DLP3D series is chip common mode choke coil array which realizes high coupling and high impedance in a small size with ferrite material technology and thin film processing technology. Features. 2 components are included in 3.2x.6mm 2. Thin type.5mm 3. High common mode Impedance characteristics (max. 44ohm, at MHz) 4. The DLP3D can suppress common mode noise without damage to signal wave..4±.2.4±.2 () (5) (2) (3) (6) (7) 3.2±.5.8±. (4) (8).3±.2.6±.5.5±.5 (in mm) Applications Common mode noise suppression of high speed differential signal lines for USB, IEEE394, LVDS.. Main board of personal computer, note PC 2. Printer, Scanner 3. LCD monitor 4. Game equipment 5. PC peripheral equipment Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLP3DN9ML4 9 ±2% 6 min. 25. max. DLP3DN3ML4 3 ±2% 2 min. 25.6 max. DLP3DN2ML4 2 ±2% min. 25 2.2 max. DLP3DN32ML4 32 ±2% 8 min. 25 3.5 max. DLP3DN44ML4 44 ±2% 7 min. 25 4.3 max. 4 Operating Temperature ange : 4 C to 85 C Equivalent Circuit ImpedanceFrequency Characteristics () (2) (3) (4) Common mode Impedance (ohm) DLP3DN47SL4 DLP3DN36SL4 DLP3DN2SL4 DLP3DN6SL4 DLP3DN9SL4 (5) (6) (7) (8) No polarity DLP3DN9SL4 DLP3DN6SL4 DLP3DN2SL DLP3DN36SL4 DLP3DN47SL4 Differential mode 99
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Monolithic Type DLM2HG Series () (3) (5) DLM2HG Series is a high quality noise suppression filter for headphone lines of high quality digital music equipment..3±.2 2.5±.2 Features. Low distortion in audio signal, Low crosstalk. 2. Effective in noise suppression both of common mode and of differential mode. 3. Small size, low profile, SMD 2.5x2.x.2mm (2) (4) (6) 2.±.2.2±.2 Application. Headphone lines of digital music equipment such as DVD, MD player. 2. Headphone lines of NotePC, PDA.4±.2.8±. (in mm) Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLM2HGN6S3 6 ±25% 6 min..4 max. Operating Temperature ange : 4 C to 85 C Equivalent Circuit ImpedanceFrequency Characteristics 4 () (3) (5) Differential Mode Common Mode (2) (4) (6) No polarity
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Winding Type DLW2S/DLW2H/DLW3S Series DLW2S Series Features. DLW2S series realizes small size and low profile. 2.x.2x.2mm 2. High common mode impedance at high frequency effects excellent noise suppression performance. 3. Various common mode impedance items of 67 to 37ohm can be used, considering noise level and signal frequency. 4. DLW2S series enables noise suppression for differential signal line without distortion in high speed signal transmission due to its high coupling. 5. Lead is not contained in the product. 6. Small dimension enables higher density packaging. DLW2S 2.±.2 () (2) (4) (3) (.45) (.45).2±.2 (.4) (.4).2±.2 (.7) (in mm) Applications. USB lines of PC, Peripheral equipment. 2. LVDS lines of NotePC, LCD. 3. USB lines of Small digital AV equipment such as digital camera. Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLW2SN67SQ2 67 ±25% 4 5 min. 25.25 max. DLW2SN9SQ2 9 ±25% 33 5 min. 25.35 max. DLW2SN2SQ2 2 ±25% 37 5 min. 25.3 max. DLW2SN8SQ2 8 ±25% 33 5 min. 25.35 max. DLW2SN26SQ2 26 ±25% 3 5 min. 25.4 max. DLW2SN37SQ2 37 ±25% 28 5 min. 25.45 max. 4 Operating Temperature ange : 4 C to 85 C Equivalent Circuit ImpedanceFrequency Characteristics DLW2S DLW2S () (2) DLW2SN37SQ2 Common mode DLW2SN26SQ2 DLW2SN8SQ2 DLW2SN2SQ2 DLW2SN9SQ2 DLW2SN67SQ2 Differential mode (4) No polarity (3) DLW2SN37SQ2 DLW2SN26SQ2 DLW2SN8SQ2 DLW2SN2SQ2 DLW2SN9SQ2 DLW2SN67SQ2.
!Note C3E9.pdf 3.3.2 DLW2H Series Features. Small size and low profile (2.x.2x.9mm). Excellent noise suppression for sets of small and thin size. 2. High common mode impedance at high frequency effects excellent noise suppression performance. 3. Various common mode impedance from 67 to 8 ohm can be used, selected depending on noise level and signal frequency. 4. Suitable for differential signal line like USB2., IEEE394 and LVDS, because DLW2H does not provide distortion to high speed signal transmission due to its high coupling. (USB2.: DLW2HN9SQ2) 5. Lead is not contained in the product. 6. Small dimension enables higher density mounting. DLW2H 2.±.2 (.45) (.45) () (2) (4) (3).9±. (.4) (.4) (.7).2±.2 Electrode () : eference Value (in mm) Applications Common mode noise suppression of signal lines in high speed and high density digital equipment such as personal computers and peripherals and telecommunication equipment. 4 Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLW2HN67SQ2 67 (Typ.) 33 5 min. 25.35 max. DLW2HN9SQ2 9 (Typ.) 33 5 min. 25.35 max. DLW2HN2SQ2 2 (Typ.) 28 5 min. 25.45 max. DLW2HN8SQ2 8 (Typ.) 25 5 min. 25.5 max. Operating Temperature ange : 4 C to 85 C DLW2H DLW2H DLW2HN2SQ2 DLW2HN8SQ2 Common mode () (2) DLW2HN9SQ2 DLW2HN67SQ2 (4) No polarity (3) DLW2HN8SQ2 DLW2HN2SQ2 DLW2HN9SQ2 Differential mode DLW2HN67SQ2. 2
!Note C3E9.pdf 3.3.2 DLW3S Series Features. DLW3S realizes small size and low profile. 3.2x.6x.9mm. 2. High common mode impedance at high frequency effects excellent noise suppression performance. 3. Various common mode impedance items of 9 to 22ohm can be used, considering noise level and signal frequency. 4. DLW3S series enables noise suppression for differential signal line without distortion in high speed signal transmission due to its high coupling. 5. Lead is not contained in the product. 6. Small dimension enables higher density packaging. DLW3S 3.2±.2 () (2) (4) (3) (.6) (.6).25±. (.6) (.6).6±.2.9±.2 (in mm) Applications. USB lines of PC, Peripheral equipment. 2. LVDS lines of NotePC, LCD. Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) Insulation esistance (M ohm) Withstand Voltage (Vdc) DC esistance (ohm) DLW3SN9SQ2 9 (Typ.) 37 5 min. 25.3 max. DLW3SN6SQ2 6 (Typ.) 34 5 min. 25.4 max. DLW3SN26SQ2 26 (Typ.) 3 5 min. 25.5 max. DLW3SN6SQ2 6 (Typ.) 26 5 min. 25.8 max. DLW3SN2SQ2 (Typ.) 23 5 min. 25. max. DLW3SN222SQ2 22 (Typ.) 2 5 min. 25.2 max. Operating Temperature ange : 4 C to 85 C Equivalent Circuit DLW3S () (2) ImpedanceFrequency Characteristics DLW3S DLW3SN222SQ2 Common mode DLW3SN2SQ2 DLW3SN6SQ2 DLW3SN26SQ2 DLW3SN6SQ2 DLW3SN9SQ2 4 (4) (3) No polarity DLW3SN222SQ2 DLW3SN2SQ2 DLW3SN6SQ2 DLW3SN26SQ2 DLW3SN6SQ2 DLW3SN9SQ2 Differential mode. 3
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Chip Common Mode Choke Coils Winding Type for Large Current DLW5AH/DLW5BS Series The DLW5AH/5BS series is high performance wound type chip common mode choke coil. * *.45 min. (T) 4.3 max. Features. High impedance (max. of 4ohm at MHz : DLW5AH) enables great noise suppression. 2. Large rated current (max. of 5A) is suitable for power line use. 3. DLW5AH/BS series does not damage high speed signal due to high coupling common mode choke coil structure. 4. Automatic mounting can be applied. DLW5AH Series.7 ±.3.3 ±.3.7 ±.3 (W) 3.6±.3 () (2) (4) (3) (L) 5.±.3.5 min. Starting position of wiring should * covered with resin..3.3 ±.3 ±.3.9 ±.3 in mm Applications. DC power lines in AC adapter of Portable equipment. 2. DC power lines of DCDC converter, battery charger. 3.6±.3 (W) 5.±.3 (L) 5.±.3.45 min. (T) 4.5 max..5 min. () (2).3 ±.3.7 ±.3 4 Part Number Common Mode Impedance (at MHz, 2 degree C) (ohm) ated Current (ma) ated Voltage (Vdc) DLW5BS Series.7 ±.3 Insulation esistance (M ohm) (4) (3).3.3 ±.3 ±.3.9 ±.3 in mm Withstand Voltage (Vdc) DC esistance (ohm) DLW5AHN42SQ2 4 (Typ.) 2 5 min. 25 3. max. DLW5BSN9SQ2 9 (Typ.) 5 5 min. 25.2 max. DLW5BSN35SQ2 35 (Typ.) 2 5 min. 25.4 max. DLW5BSN2SQ2 (Typ.) 5 5 min. 25.6 max. DLW5BSN52SQ2 5 (Typ.) 5 min. 25. max. DLW5BSN32SQ2 3 (Typ.) 5 5 min. 25.3 max. Operating Temperature ange : 25 C to 85 C Equivalent Circuit ImpedanceFrequency (Typical) () (2) Common mode DLW5AHN42SQ2 DLW5BSN32SQ2 DLW5BSN52SQ2 DLW5BSN2SQ2 DLW5BSN35SQ2 DLW5BSN9SQ2 (4) (3) No polarity DLW5AHN42SQ2 DLW5BSN32SQ2 DLW5BSN52SQ2 DLW5BSN2SQ2 DLW5BSN35SQ2 DLW5BSN9SQ2 Differential mode 4
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Ferrite Beads Inductors Part Numbering Ferrite Beads Inductors (Global Part Number) BL q 2 w N e 2 r t M y 2 u B i qproduct ID Product ID BL wseries Code 2 3 ebeads Core Material Code N rnumbers of Beads Core Code 2 Ferrite Beads Inductors Series Beads ø3.6 Beads ø3.4 Beads ø2.3 max. Beads Core Material Standard Type Numbers of Beads Core 2 ylead Length, Space Code Lead Length, Space Series A Bulk, Axial Type, 3.7mm D Bulk, Axial Type, 45.mm E Taping Axial Type, 26.mm BL F Taping, Axial Type, 52.mm J Bulk, adial Type, 5.mm M Bulk, adial Type,.mm N Taping, adial Type, 6.5mm BL2/BL3 P Taping, adial Type, 8.5mm Q Taping, adial Type, 2.mm ulead Diameter Code Lead Diameter 2 ø.6mm ø.65mm tlead Type Code Lead Type A A2 2 3 Axial Straight Type Axial Crimp Type adial Straight Type adial Straight and wave formed Leads Type adial Crimp Type ipackaging Code Packaging Series A B J Ammo Pack Bulk Paper eel (ø32mm) BL/BL2/BL3 All series BL 5 5
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Ferrite Beads Inductors BL/BL2/BL3 Series Features BL/2/3 series are ferrite beads with lead wires to produce a high frequency loss for suppression of noise. Simple construction and easytouse. Effective for low impedance circuits such as power supplies and grounds. Effective also for preventing overshoot and undershoot the digital signal in clocks or the like, and suppressing the higher harmonic wave. Suitable for prevention of abnormal oscillation at high frequency amplifying circuit. BLNAD2B ø3.6±.5 ø.65 2 min. 5.±.3 2 min. 45 min. Coating extending on leads :.5 max. (in mm) 7.5 max. ø3.4±.2 ø.65 3.7±. 7.5 max. ±. 5. min. ø3.6±.5.±. 5.±.8 ø.65 BLNA2A2B 5.±.3 BL2N2M2B Coating extending on leads :.5 max. (in mm) There is excess bond stick on the wire. (in mm) 8. max. ø3.4±.2 9.max 3.4±.2 7.5max 5 BL2N3J2B 2. max. 5.±. 5.±.8 5. min. ø.65 BL2N2M2B.±. 5.±.8 5.min φ.65 There is excess bond stick on the wire. (in mm) (in mm) 9. max. ø3.4±.2 8.3max 2.3max BL2N23J2B 2. max. 5.±. 5.±.8 5. min. ø.65 BL3N2MB 6.5max.±. 5.±.8 5.min φ.6 (in mm) (in mm) 6
!Note C3E9.pdf 3.3.2 Part Number ated Current (A) Operating Temperature ange ( C) BLNAD2B 7 4 to 85 BLNAEA 6 4 to 85 BLNAFJ 6 4 to 85 BLNA2A2B 7 4 to 85 BL2N2M2B 7 4 to 85 BL2N2NA 6 4 to 85 BL2N2PA 6 4 to 85 BL2N2QA 6 4 to 85 BL2N3J2B 7 4 to 85 BL2N3NA 6 4 to 85 BL2N2M2B 7 4 to 85 BL2N2NA 6 4 to 85 BL2N2PA 6 4 to 85 BL2N2QA 6 4 to 85 BL2N23J2B 7 4 to 85 BL2N23NA 6 4 to 85 BL3N2MB 6 4 to 85 BL3N2NA 6 4 to 85 BL3N2PA 6 4 to 85 BL3N2QA 6 4 to 85 Equivalent Circuit (esistance element becomes dominant at high frequencies.) ImpedanceFrequency Characteristics 5 6 BLN 6 BL2N 4 4 2 2 8 6 8 6 4 2 4 2.5 2 5 2 5 2 5.5 2 5 2 5 2 5 Continued on the following page. 7
!Note C3E9.pdf 3.3.2 Continued from the preceding page. ImpedanceFrequency Characteristics 6 BL2N2 6 BL3N2 4 4 2 2 8 6 4 8 6 4 2 2.5 2 5 2 5 2 5.5 2 5 2 5 2 5 5 8
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Disc Type EMIFILr Part Numbering Disc Type EMIFILr (Global Part Number) DS q S w 9 H B3 2E 27 Q55 B e r t y u i o qproduct ID Product ID DS wstructure Code N S T Threeterminals Capacitor Structure No Ferrite Beads Type Builtin Ferrite Beads Type with Ferrite Beads Type ttemperature Characteristics Code Capacitance Change B3 ±% (Temperature ange : 25 C to +85 C) C5 ±22% (Temperature ange : 25 C to +85 C) D3 +2/3% (Temperature ange : 25 C to +85 C) E3 +2/55% (Temperature ange : 25 C to +85 C) E5 +22/56% (Temperature ange : 25 C to +85 C) F3 +3/8% (Temperature ange : 25 C to +85 C) 8 +3/85% (Temperature ange : C to +6 C) estyle Code 6 9 rcategory Code N H ilead Type/oPackaging Style Diameter 8.mm Type Diameter 9.5mm Type Category for General Use for Heavyduty yated Voltage Code C H 2A 2E ated Voltage 6V 5V V 25V ucapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. Code Lead Type Lead Length* (in mm) Packaging Series Q55B 25. min. All series Q5B 4.±.5 DST9N/H Q52B Straight 6.±. DST9N Q54B Q56B 4.±.5 6.±. Bulk DSN6/9, DSS6/9 5 T4B T5B Incrimp 4.±.5 25. min. DSS6N Q9J 2.±. DSS9N/H, DST9N Q92J Q93J Q9A Straight 6.5±. 8.5±. 2.±. Paper eel (ø32mm) DSS9N/H DSp6, DSN9N/H Q92A Q93A 6.5±. 8.5±. Ammo Pack All series except DSS9N/H U2A U3A Incrimp 6.5±. 8.5±. DSS6N *Lead Distance between eference and Bottom Planes except Bulk. 9
I I OnBoard Type (DC) EMI Suppression Filters (EMIFILr) I!Note C3E9.pdf 3.3.2 Disc Type EMIFILr DSN6/DSS6 Series Features DS_6 is comnpact, high performance lead type EMI suppression filter which can be mounted 2.54mm pitch. Its 3terminal structure enables nice high frequency performance. 7. max. 2.54 max. 8. max. 2.5±.5 5.±.5 I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 DSN6_Q55B Series GND ø.6 (in mm) 8. max. 2.54 max. * 8. max. 2.54 max. * *2. max. *2 7. max. 2.5±.5 I T52 Type : 25. min. T4 Type : 4.±.5 2.5±.5 5.±.5 I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 5.±.5 ø.6 ø.6 DSS6_T5B Series Incrimp Type GND (in mm) * There may be a hole on the top of ferrite beads, which cause no characteristics deterioration. *2 Bottom of the ferrite beads may not be level with each other. DSS6_Q55B Series Straight Type GND (in mm) * There may be a hole on the top of ferrite beads, which cause no characteristics deterioration. *2 Bottom of the ferrite beads may not be level with each other. DSN6 Series 5 Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSN6NC5H22 22 +2%,2% 5 6 25 to 85 DSN6NC5H33 33 +2%,2% 5 6 25 to 85 DSN6NC5H47 47 +2%,2% 5 6 25 to 85 DSN6NC5H +2%,2% 5 6 25 to 85 DSN6NC5H27 27 +2%,2% 5 6 25 to 85 DSN6NC5H2 +2%,2% 5 6 25 to 85 DSN6NC5H222 22 +2%,2% 5 6 25 to 85 DSN6N8H3 +8%,2% 5 6 25 to 85 Please refer to Part Numbering for Type and Length of Lead.
!Note C3E9.pdf 3.3.2 Equivalent Circuit Insertion Loss Characteristics (Typical) 2 8 7 6 (5Ω 5Ω) 2 5 4 3 Insertion Loss (db) 4 6 8 : 22pF 2 : 33pF 3 : 47pF 4 : pf 5 : 27pF 6 :pf 7 : 22pF 8 : pf GND No polarity 2. Builtin Ferrite Beads DSS6 Series Incrimp Type Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSS6NC52A22 22 +2%,2% 6 25 to 85 DSS6NC52A33 33 +2%,2% 6 25 to 85 DSS6NC52A47 47 +2%,2% 6 25 to 85 DSS6NC52A +2%,2% 6 25 to 85 DSS6NC52A5 5 +2%,2% 6 25 to 85 DSS6NC52A22 22 +2%,2% 6 25 to 85 DSS6NC52A27 27 +2%,2% 6 25 to 85 DSS6NC52A47 47 +2%,2% 6 25 to 85 DSS6NC52A2 +2%,2% 6 25 to 85 DSS6NE52A222 22 +8%,2% 6 25 to 85 DSS6N82A3 +3%,3% 6 25 to 85 DSS6NF3C223 22 +8%,2% 6 6 25 to 85 Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) GND No polarity Insertion Loss (db) 2 4 6 8 2 9 8 5 7 4 6 3 2 : 22pF 2 : 33pF 3 : 47pF 4 : pf 5 : 5pF 6 : 22pF 7 : 27pF 8 : 47pF 9 : pf : 22pF : pf 2 : 22pF 5 2.
!Note C3E9.pdf 3.3.2 Builtin Ferrite Beads DSS6 Series Straight Type Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSS6NC52A22 22 +2%,2% 6 25 to 85 DSS6NC52A33 33 +2%,2% 6 25 to 85 DSS6NC52A47 47 +2%,2% 6 25 to 85 DSS6NC52A +2%,2% 6 25 to 85 DSS6NC52A5 5 +2%,2% 6 25 to 85 DSS6NC52A22 22 +2%,2% 6 25 to 85 DSS6NC52A27 27 +2%,2% 6 25 to 85 DSS6NC52A47 47 +2%,2% 6 25 to 85 DSS6NC52A2 +2%,2% 6 25 to 85 DSS6NE52A222 22 +8%,2% 6 25 to 85 DSS6N82A3 +3%,3% 6 25 to 85 DSS6NF3C223 22 +8%,2% 6 6 25 to 85 Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) Insertion Loss (db) 2 4 6 8 2 9 8 (5Ω 5Ω) 2 5 4 3 7 6 : 22pF 2 : 33pF 3 : 47pF 4 : pf 5 : 5pF 6 : 22pF 7 : 27pF 8 : 47pF 9 : pf : 22pF : pf 2 : 22pF GND No polarity 2. 5 2
I I OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Disc Type EMIFILr Broad Type DSN9/DSS9/DST9 Series I!Note C3E9.pdf 3.3.2 Features DS_9 is a basic type EMI suppression filter which can obtain high insertion loss in a wide frequency range. Its 3terminal structure enables nice high frequency performance. DSS9NP32A222/DSS9NT3H223 are low distortion type for audio circuits. 2.5±.5.5 max. 5.±.5 9.5 max.. max..±.5 4. max. ø.65 DSN9N_Q55B GND I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 (in mm) 2. max. 7.5 max. 9.5 max. 4. max. 2.5±.5.5 max. 5.±.5.5 max. Ferrite bead * 2.5±.5 2.5±.5.5 max. 5.5 max. Ferrite bead ø.65 5.±.5 I.25±.5 DSS9N_Q55B GND I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 (in mm) * Bottom of the ferrite beads may not be level with each other. DST9N_Q55B GND Q55 Type : I=25. min. Q52 Type : I=6.±. Q5 Type : I=4.±.5 ø.65 (in mm) DSN9 Series Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSN9NC52A27 27 +2%,2% 7 25 to 85 DSN9NC52A222 22 +2%,2% 7 25 to 85 DSN9NC5H223 22 +5%,2% 5 7 25 to 85 DSN9NC5C4 +2%,2% 6 7 25 to 85 5 ated current is 6A for taping type. Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 27pF 22pF 2 Insertion Loss (db) 4 6 22pF pf GND No polarity 8.. 3
!Note C3E9.pdf 3.3.2 Builtin Ferrite Beads DSS9 Series Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSS9NC52A22 22 +2%,2% 7 25 to 85 DSS9NC52A47 47 +2%,2% 7 25 to 85 DSS9NC52A +2%,2% 7 25 to 85 DSS9NC52A27 27 +2%,2% 7 25 to 85 DSS9NC52A222 22 +2%,2% 7 25 to 85 DSS9NP32A222 22 +2%,2% 7 25 to 85 DSS9NC5H223 22 +5%,2% 5 7 25 to 85 DSS9NT3H223 22 +5%,2% 5 7 25 to 85 ated current is 6A for taping type. DSS9NP32A222/DSS9NT3H223 are low distortion types for audio IF circuits. Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 27pF pf 47pF 22pF Insertion Loss (db) 2 4 6 22pF(DSS9NB32A222) 22pF(DSS9NP32A222) 22pF(DSS9ND3H223) 22pF(DSS9NT3H223) GND No polarity 8.. With Ferrite Beads DST9 Series 5 Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DST9NC52A27 27 +2%,2% 7 25 to 85 DST9NC52A222 22 +2%,2% 7 25 to 85 DST9NC5H223 22 +5%,2% 5 7 25 to 85 ated current is 6A for taping type. Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) 2 22pF 27pF Insertion Loss (db) 4 6 22pF GND No polarity 8.. 4
I I OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Disc Type EMIFILr Heavyduty Type DSN9H/DSS9H/DST9H Series I!Note C3E9.pdf 3.3.2 Features DS_9H is a basic type EMI suppression filter which can obtain high insertion loss in a wide frequency range. Its threeterminal structure enables nice high frequency performance. High rated voltage of 25Vdc and wide operating temperature range from 4 degree C to 5 degree C are suitable for high reliability circuits. 2.5±.5.5 max. 5.±.5 9.5 max.. max..±.5 4. max. ø.65 DSN9H_Q55B GND I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 (in mm) 2. max. 7.5 max. 9.5 max. 4. max. 2.5±.5.5 max. 5.±.5.5 max. Ferrite bead * 2.5±.5 2.5±.5.5 max. 5.5 max. Ferrite bead ø.65 5.±.5 I.25±.5 DSS9H_Q55B GND I Q55 Type : 25. min. Q56 Type : 6.±. Q54 Type : 4.±.5 (in mm) * Bottom of the ferrite beads may not be level with each other. DST9H_Q55B GND Q55 Type : I=25. min. Q52 Type : I=6.±. Q5 Type : I=4.±.5 ø.65 (in mm) DSN9H Series Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSN9HB32E22 22 +2%,2% 25 6 4 to 5 DSN9HB32E +2%,2% 25 6 4 to 5 DSN9HB32E27 27 +2%,2% 25 6 4 to 5 DSN9HB32E222 22 +2%,2% 25 6 4 to 5 5 Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) pf 22pF (5Ω 5Ω) 2 22pF 27pF Insertion Loss (db) 4 6 8 GND No polarity 2. 5
!Note C3E9.pdf 3.3.2 Builtin Ferrite Beads DSS9H Series Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DSS9HB32E22 22 +2%,2% 25 6 4 to 5 DSS9HB32E +2%,2% 25 6 4 to 5 DSS9HB32E27 27 +2%,2% 25 6 4 to 5 DSS9HB32E222 22 +2%,2% 25 6 4 to 5 Please refer to Part Numbering for Type and Length of Lead. Equivalent Circuit Insertion Loss Characteristics (Typical) 2 27pF 22pF pf (5Ω 5Ω) GND No polarity Insertion Loss (db) 4 6 8 22pF 2. With Ferrite Beads DST9H Series Part Number Capacitance (pf) ated Voltage (Vdc) ated Current (A) Operating Temperature ange ( C) DST9HB32E22 22 +2%,2% 25 6 4 to 5 DST9HB32E +2%,2% 25 6 4 to 5 DST9HB32E27 27 +2%,2% 25 6 4 to 5 DST9HB32E222 22 +2%,2% 25 6 4 to 5 Please refer to Part Numbering for Type and Length of Lead. 5 Equivalent Circuit Insertion Loss Characteristics (Typical) Insertion Loss (db) 2 4 6 8 27pF 22pF pf 22pF (5Ω 5Ω) GND No polarity 2. 6
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Lead Type EMIGUADr (EMIFILr with Varistor Function) Part Numbering Lead Type EMIGUADr (EMIFILr with Varistor Function) (Global Part Number) VF q S w 6 e V r D8 t E y 22 u T5 i B o qproduct ID rfeatures Product ID Code Features VF EMIGUADr Lead Type V with Varistor Function wstructure Code S Structure Builtin Ferrite Beads Type with esistance ttemperature Characteristics Code Capacitance Change D8 +2/3% (Temperature ange : 4 Cb+5 C) D3 +2/3% (Temperature ange : 25 Cb+85 C) estyle Code 3 6 9 ilead Type/oPackaging Style Size is expressed by a figure yated Voltage Code E B ated Voltage 25V 2V ucapacitance Expressed by three figures. The unit is in picofarad (pf). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. Code Lead Type Lead Length* Packaging Series T5B U3A Incrimp 25.mm min. 8.5+/.mm Bulk Ammo Pack VF3/VFS6 Q55B 25.mm min. Bulk Q9J Q92J Straight 2.+/.mm 6.5+/.mm Paper eel (ø32mm) VFS9 Q93J 8.5+/.mm *Lead Distance between eference and Bottom Planes except Bulk. 5 7
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Lead Type EMIGUADr (EMIFILr with Varistor Function) VF3V/VFS6V/VFS9V Series for Semiconductor Protection VF3V Series Features The VF3V series is designed for ESD surge protection of IC. It efficiently absorbs ESD surges rushed into IC's I/O terminals. No. Pin Indicator (Surge entrance side) 8. max. 5. max. 2.3 max. Applications Elimination of noise and protection of semiconductors in office equipment, including computers and peripheral equipment, copy machines, and communication terminals. 2.5±.5 5.±.5 () (2) (3) 25. min. ø.45±. (in mm) Part Number ated Voltage (Vdc) Varistor Voltage (Vdc) Capacitance (pf) ated Current (ma) Peak Pulse Current (A) Operating Temperature ange ( C) VF3VD3E3 25 5 +2%,2% 3 +2%,2% 2 5 25 to 85 Please refer to Part Numbering for Type and Length of Lead. Insertion Loss Characteristics (5Ω 5Ω) 2 Insertion Loss (db) 3 4 5 5 6 7 5 8
!Note C3E9.pdf 3.3.2 for SignalLine VFS6V Series Features The VFS6V series is designed for surge protection of signal line. It protects electric circuit from surges such as static electricity and suppresses EMI noise. Builtin ferrite bead gives excellent EMI suppression. Applications Elimination of noise and protection of electric circuits in office equipment, including computers and peripheral equipment, copy machines, and communication terminals. 2.5±.5 *2 5.±.5 8. max. 2.54 max. GND (in mm) * There may be a hole on the top of ferrite beads, which cause no characteristics deterioration. *2 Bottom of the ferrite beads may not be level with each other..5 max. 25. min. * ø.6 Part Number ated Voltage (Vdc) Varistor Voltage (Vdc) Capacitance (pf) ated Current (A) Peak Pulse Current (A) Operating Temperature ange ( C) VFS6VD8E22 25 5 +2%,2% 22 +2%,2% 6 4 to 5 Please refer to Part Numbering for Type and Length of Lead. Insertion Loss Characteristics (5Ω 5Ω) Insertion Loss (db) 2 4 6... 5 9
!Note C3E9.pdf 3.3.2 for LargeCurrent VFS9V Series Features The VFS9V series is designed for surge protection of the power supply line. It protects electric circuits from surges such as static electricity and suppresses EMI noise. Its large capacitance value enables high insertion loss for EMI noise. 2.5±.5.5 max. 5.±.5 2. max. 7.5 max. Ferrite bead * 2.5±.5.5 max. 25. min. Applications For circuit protection and noise suppression in electronics equipment such as computers and DC motors, and in electronics systems installed in cars such as car audio equipment and engine controllers. ø.65 GND (in mm) * Bottom of the ferrite beads may not be level with each other. Part Number ated Voltage (Vdc) Varistor Voltage (Vdc) Capacitance (pf) ated Current (A) Operating Temperature ange ( C) VFS9VD3B223 2 22 +2%,2% 22 +5%,2% 7 4 to ated current: 6A (Taping Type)/7A (Bulk Type) Please refer to Part Numbering for Type and Length of Lead. Insertion Loss Characteristics VoltageCurrent Characteristics (5Ω 5Ω) 3 2 2 Attenuation (db) 4 6 8 Current (ma) 4 3 2 2 3 4..5 5 5 5 2 5 3 Voltage (V) 2
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect of VF/VFS Series!Example of IC Protection " Testing Method. Put ESD surge to IC (744 family) input terminal with ESD simulator based on IEC 82. 2. Check IC's operation. 3. If IC's operation is normal, increase ESD voltage in kv step. 4. Continue above steps to 3 till IC's operation becomes abnormal. [Test Circuit] ESD Simulator 33Ω 5pF VF3V Test IC " esult (esult) Breakdown level [kv] 3min.,,,,,, 25 2 5 5 Without VF3V With use VF3V LS ALS AS C IC s Family HC AC!Example of EMI Suppression Effect [Test Circuit] ANT Signal MHz ACO4 F Noise adiation Cable (5cm) Shield Type of Filter EMI Suppression Effect Description 5 Before Countermeasures (No Filters) Noise Level [dbµv/m] 7 6 5 4 3 2 3 9 5 2 27 33 Frequency [MHz] Use VF3VD3E3T5 Noise Level [dbµv/m] 7 6 5 4 3 2 3 9 5 2 27 33 Frequency [MHz] 2
!Note C3E9.pdf 3.3.2 Noise EMI Suppression Effect Effect of VF/VFS Series!Features (VFS9V) Items Overload Test methods.4 times the varistor voltage (V) is applied for 5 minutes at room temperature. ated values Surge Test () At room temperature. Surges are applied are 5 times every 2 seconds. Then after or 2 hours, the sample is measured. 4V.47µF Items ated Capacitance Change Specifications WithinT5% Surge Test (2) At room temperature. Capacitor "C" is changed with 7V, then dischanged to apply the voltage to the sample. Tested once (resuming JASO A). 7V.8Ω 2W C C=mF Insulation esistance ated of Change in Varistor Voltage V* Voltage ate 5kΩ min WithinT5%.3 max High Temperature Load At a temperature of 85±3D. The varistor voltage V is continuously applied to the sample for to 24 hours. Then it is left at room temperature, for 4 to 24 hours before measuring. *V : Voltage when ma is applied!pulsevoltage Breakdown Characteristic (VFS9V) The VFS9V EMIGUADr use a self healing varistorcapacitor, so that it can be used under a 5 to 6V surge which would break conventional disk type EMI filters. As shown in figure below the EMIGUADr withstands 2V impulses applied times. 5Ω 5Ω VFS9V Capacitance:.22µF with varistor function 5 esidual ate [%] 5 3terminal capacitor Capacitance:.22µF with no varistor function 5 5 2 Pulse Voltage Applied [V] V 8ns esidual ratio when pulses are applied!temperature Characteristics of Varistor VoltageInsulation esistance (VFS9V) Insulation esistance [MΩ] 4 3 2 Insulation resistance Change rate of varistor voltage 3 3 6 9 Temperature [D] + Change ate of Varistor Voltage [%] Continued on the following page. 22
!Note C3E9.pdf 3.3.2 EMI Suppression Effect Noise Suppression Effect of VF/VFS Series Continued from the preceding page.!noise Absorption Effect of EMIGUADr Type of Filter EMI Suppression Effect Description without EMIGUADr 9 8 : 2V/div : ns/div Waveform when EMIGUADr is not used. (Surge from a noise simulator) 2 % with EMIGUADr D 223S 222 9 8 : 2V/div : ns/div Waveform after the noise passed through EMIGUADr. Little noise is recorded. 2 %!Comparative Data. Absorption of quickrising, highfrequency noise (ns/div, V/div) Type of Filter EMI Suppression Effect Description 5ns without Filters 2V Noise wave applied Conventional varistor 9 8 As with the 2terminal capacitor 2 % 5 2terminal capacitor (with varistor function) 9 8 2 % The 2terminal capacitor is influenced by lead line inductance, leaving behind some of the rising and falling edges. The residual noise can cause the system to malfunction. VFS9V 9 8 2 % The 3terminal structure eliminates most of the lead line inductance. This allows the VFS9V to completely absorb the rising and falling edges of the applied pulses. Continued on the following page. 23
!Note C3E9.pdf 3.3.2 Noise EMI Suppression Effect Effect of VF/VFS Series Continued from the preceding page. 2. Absorption of widepulse noise (5ns/div, 2V/div) Type of Filter EMI Suppression Effect Description 2ns without Filters 3V Noise wave applied 2terminal capacitor 9 8 In capacitors the voltage of the residual surge (3V) is higher than that of the above example. The wave height is almost the same as the original. 2 % 3terminal capacitor (with ferrite bead) 9 8 2 % Conventional EMI filters do not work for widepulse noise because capacitors are saturated. In this example, the residual 2V surge can cause the system to breakdown. VFS9V 9 8 Bypassing the high voltage to the ground, voltage can be surppressed. 2 % 5 24
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Block Type EMIFILr BN Series BN Series 2.±.5.±.5 The block type "EMIFIL" BN series incorporates throughtype capacitor, monolithic chip capacitors and bead. The BN is high performance for use in DC power circuits. 3.5±. ø.8.8 ±. 3 max. 8 max. 5.±.5 ø.8 ø.8.6 ±. Features. The filter enables obtaining high insertion loss in wide frequency ranges from.5mhz to GHz. 2. The only one filter block enables noise suppression of both the positive and negative lines. 3. There are no connection routes in the current circuits, thus ensuring highly reliable performance. BN2/BN3 CG PSG 7.5±.2 2.5±.2 B 2.±.5 CB CG 2.5±.2 2.5±.2 PSG : Power supply ground CG : Load circuit ground CB : Load circuit + Bias.±.5 (in mm) Applications Noise elimination from DC power sources in a variety of switching power sources, engine control units, digital equipment and computer terminals. 3.5±. ø..8 ±. 3.5 max. 8.5 max. 5.±.5 ø. ø..6 ±. 2.5±.2 2.5±.2 7.5±.2 2.5±.2 B N 5 BN5 CG CB CG PSG : Power supply ground CG : Load circuit ground CB : Load circuit + Bias PSG B (in mm) Part Number ated Voltage (Vdc) Withstand Voltage (Vdc) ated Current (A) Insulation esistance (min.) (M ohm) Insertion Loss BN2 5 25 MHz to GHz:4dB min.(2 to 25 C line impedance=5 ohm) BN3 5 375 5MHz to GHz:4dB min.(2 to 25 C line impedance=5 ohm) BN5 5 25 5 MHz to GHz:4dB min.(2 to 25 C line impedance=5 ohm) Operating Temperature ange : 3 C to 85 C 5 Equivalent Circuit Insertion Loss Characteristics (Typical) (5Ω 5Ω) BN3 L L3 C2 () B CB (2) L2 C (3) PSG CG (4) Insertion Loss (db) 2 4 6 BN2 (BN5) ()(4) : Terminal Number PSG : Power Supply Ground CG : Circuit Ground CB : Circuit+B 8... 25
!Note C3E9.pdf 3.3.2 Noise EMI Suppression Effect Effect of BN Series!Suppression of DC Side ipple of the Switching Power Supply [Testing Circuit] BN2 Switching Power Supply +5V CG Type of Filter EMI Suppression Effect Description High frequency noise, max..5v, can be seen. When BN2 is not used +5.V 5µs/div.2V/div Noise can be almost suppressed by BN2. When BN2 is used +5.V 5µs/div.2V/div 5 26
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Common Mode Choke Coils Part Numbering Common Mode Choke Coils (Global Part Number) PL q T w 9 e H r N t 2 y 3 u P i o B! qproduct ID Product ID PL wtype Code T eapplications Code 9 rstructure Code H tfeatures Code N Common Mode Choke Coils Type DC Type Applications for DC Line Highfrequency Type Structure Core Horizontal Type Features General Use yinductance Expressed by three figures. The unit is microhenry (µh). The first and second figures are significant digits, and the third figure expresses the number of zeros which follow the two figures. If there is a decimal point, it is expressed by the capital letter "". In this case, all figures are significant digits. If inductance is less than. µh, the inductance code is expressed by a combination of two figures and the capital letter "N", and the unit of inductance is nanohenry (nh). The capital letter "N" indicates the unit of "nh", and also expresses a decimal point. In this case, all figures are significant digits. uated Current Expressed by three figures. The unit is in amperes (A). A decimal point is expressed by the capital letter "". In this case, all figures are significant digits. iwinding Mode Code P olead Dimensions Code Winding Mode Aligned Winding Type Lead Dimensions 5mm!Packaging Code Packaging Series B Bulk All series 5 27
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Common Mode Choke Coils (for DC Line) PLT9H Series The PLT9H series is common mode choke coil for DC line. It is effective against the common mode noise that can cause radiative noise in power supply lines and interface lines. The additional normal mode inductance enables high suppression effect to radiation noise. Features. This is a wide frequency range type, applicable in applications ranging from a few MHz to several MHz. 2. It features a lowprofile design. Applications. Noise suppression of SW power supply, DCDC converter. 2. DC power lines in AC adapter of Portable equipment. 4 max. 3 max. 5± 8 max. 5±.5 Soldered ±.5 () (2) (4) (3) ø.6 max. (in mm) Part Number Common Mode Inductance (µh) ated Current (A) ated Voltage (Vdc) Withstand Voltage (Vdc) PLT9HN23P 2 min. 3 5 25 Operating Temperature ange : 4 C to 85 C Equivalent Circuit Insertion Loss Characteristics (Typical) 5 5 () (2) Insertion Loss (db) 5 2 (4) (3) 25 No polarity 3. 28
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Microwave Absorbers Part Numbering Microwave Absorber (Global Part Number) EA q 26 w A e 6 r M t 2 y 2 u qproduct ID Product ID EA Microwave Absorber wsheet Type Code pp 27 2 Sheet Type Iron carbonyl type Metal Flake Powder (non Halogen type) Metal Flake Powder (UL certified type) eadhesive Tape Type Code A B L U Adhesive Tape Type Standard tape type Thin Adhesive tape type No tape type UL certified type rsheet Thickness Expressed by 3 digits including the second decimal place in mm. Ex.) Code Sheet Thickness 2.2mm tunit of Dimension One capital lettler expresses Unit of dimension (y) and Dimensions Length (u). Code M C Standard shape is a rectangle. Please contact us for other shapes. Unit of Dimension in mm (Standard) in cm (Standard) ydimension (Length) Expressed by 3 digits including the first decimal place. udimension (Width) Expressed by 3 digits including the first decimal place. Ex.) Code M35 C5 Dimension (Length g Width) 3.g5. mm 5.g. cm 6 29
!Note C3E9.pdf 3.3.2 OnBoard Type (DC) EMI Suppression Filters (EMIFILr) Microwave Absorbers EA/EA2/EA2 Series EA Series Features. Excellent elasticity and durability with silicon rubber. 2. Suitable for prevention of abnormal oscillation in high frequency modules, suppression of spurious spectra and prevention interference between circuits. 3. Holds easily in equipment with adhesive tape. Part Number Applicable Frequency Thickness (mm) Flame esistance Halogen Operating Temperature ange EA26A 2. GHz (Typ.). (Typ.) Halogen Free 4 to +8 C EA26A6.5 GHz (Typ.).6 (Typ.) Halogen Free 4 to +8 C EA26A8. GHz (Typ.).8 (Typ.) Halogen Free 4 to +8 C EA46A8 5.8 GHz (Typ.).8 (Typ.) UL94V Halogen Free 4 to +8 C EA75A27 2.5 GHz (Typ.) 2.7 (Typ.) UL94V Halogen Free 4 to +8 C efrection Loss 5 eflection Loss (db) 5 2 25 3 EA75A27 EA46A8 EA26A8 EA26A6 EA26A 35 4 2 4 6 8 2 4 6 8 2 Frequency(GHz) 6 3
!Note C3E9.pdf 3.3.2 EA2/2 Series Features. Magneticallyshielded highmicro and highloss characteristics can suppress noise in a wide frequency band for digital equipment. 2. Thin (.2mm.mm) and flexible sheet makes easy handling in assembly process. 3. Holds easily in equipment with adhesive tape. 4. EA2xx series : Non Halogen type EA2xx series : UL94V certified material is used. Part Number Applicable Frequency Thickness (mm) Flame esistance Halogen Operating Temperature ange EA27A2. 3.GHz (Typ.).2 (Typ.) Halogen Free 4 to +5 C EA27A5. 3. GHz (Typ.).5 (Typ.) Halogen Free 4 to +5 C EA27A. 3. GHz (Typ.). (Typ.) Halogen Free 4 to +5 C EA27B5. 3. GHz (Typ.).5 (Typ.) Halogen Free 4 to +5 C EA27B. 3. GHz (Typ.). (Typ.) Halogen Free 4 to +5 C EA27B3. 3. GHz (Typ.).3 (Typ.) Halogen Free 4 to +5 C EA27B2. 3. GHz (Typ.).2 (Typ.) Halogen Free 4 to +5 C EA27B5. 3. GHz (Typ.).5 (Typ.) Halogen Free 4 to +5 C EA2A2. 3. GHz (Typ.).2 (Typ.) UL94V 4 to +5 C EA2A5. 3. GHz (Typ.).5 (Typ.) UL94V 4 to +5 C EA2A. 3. GHz (Typ.). (Typ.) UL94V 4 to +5 C EA2B2. 3. GHz (Typ.).2 (Typ.) UL94V 4 to +5 C EA2B5. 3. GHz (Typ.).5 (Typ.) UL94V 4 to +5 C EA2B. 3. GHz (Typ.). (Typ.) UL94V 4 to +5 C Magnetic Permeabilityeluctance (Typical) 2 6 µ" 2 8 4.. Frequency (GHz) 6 3
!Note C3E9.pdf 3.3.2 Chip EMIFILr!Caution/Notice!Caution (Soldering and Mounting) Give special attention when mounting chip "EMIFIL" BLM_P/NFM_P series close to other products that radiate heat. The excessive heat by other products may cause deterioration of the insulation resistance and result in excessive heat or fire. Notice (Storage and Operating Conditions) < Operating Environment > Do not use products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. < Storage and Handling requirements >. Storage Period BLM/BLA/VFM4/DLP3S/DLM2HG series should be used within 6 months, the other series should be used within 2 months. Solderability should be checked if this period is exceeded. 2. Storage conditions () Storage temperature : to 4 degree C elative humidity : 3 to 7% Avoid sudden changes in temperature and humidity. (2) Do not store products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. Notice (ating) Noise suppression levels resulting from MUATA's EMI suppression filters "EMIFIL" may vary, depending on the circuits and ICs used, type of noise, mounting pattern, lead wire length, mounting location, and other operating conditions. Be sure to check and confirm in advance the noise suppression effect of each filter, in actual circuits, etc. before applying the filter in a commercialpurpose equipment design. Notice (Soldering and Mounting) < Operating Environment > Do not use products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. < Storage and Handling requirements >. Storage Period Products inspected by Murata over 2 months ago should be examined prior to use. Date can be confirmed with inspection No. marked on the container. Solderability should be checked if this period is exceeded. (NFM4P/55P, VCM series should be used within 6 months.) 2. Storage conditions () Storage temperature : to 4 C. elative humidity : 3 to 7% Avoid sudden changes in temperature and humidity. (2) Do not store products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. 6 32
!Note C3E9.pdf 3.3.2 Lead Type EMIFILr!Caution/Notice!Caution (ating) Do not use products beyond the rated current and the rated voltage, or deterioration of the insulation resistance may result in excessive heat or fire.!caution (Soldering and Mounting) Mounting holes should be designed as specified in these specifications. Other design than shown in these specifications may cause cracks in ceramics which may lead to smoking or firing. Notice (Storage and Operation Condition) < Operating Environment >. Do not use products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. 2. Do not use products near water, oil or organic solvents. Avoid environment where dust or dirt may adhere to product. < Concerned to "EMIGUAD" > VF3V series is designed only to absorb electrostatic surges. Do not use this product to absorb large energy surges such as lightning or switching related surges. < Storage and Handling equirements >. Storage Period Use the products within 2 months after delivery; solderability should be checked if this period is exceeded. 2. Storage conditions () Storage temperature : to 4 degree C elative humidity : 3 to 7% Avoid sudden changes in temperature and humidity. (2) Do not store products in a chemical atmosphere such as chlorine gas, acid or sulfide gas. (3) When restoring taping type (BLNFJ), please attach the Spacer between flanges of reel. The Spacer is corrugated paper which is attached when shipping. Notice (ating) Noise suppression levels resulting from MUATA's EMI suppression filters "EMIFIL" may vary, depending on the circuits and ICs used, type of noise, mounting pattern, lead wire length, mounting location, and other operating conditions. Be sure to check and confirm in advance the noise suppression effect of each filter, in actual circuits, etc. before applying the filter in a commercialpurpose equipment design. 6 33
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting). Standard Land Pattern Dimensions The capacitor type Chip EMIFILr (NFp series) / Chip EMIGUADr (VFM series) suppress noise by conducting the highfrequency noise element to ground. Therefore, to obtain maximum performance from these filters, the ground pattern should be made as large as possible during the PCB design stage. As shown in the right, one side of the PCB is used for chip mounting, and the other is used for grounding. Small diameter feedthrough holes are then used to connect the grounds on each side of the PCB. This reduces the highfrequency impedance of the grounding and maximizes the filter's performance. Please contact us if using a thinner land pad than 8µm for NFM55P. BLM3 BLM5 BLM8 BLM2 BLM3 BLM4 oeflow and Flow BLM Series (Except BLMppP series) c BLMppP c d (pattern) Land Pattern + Solder esist Land Pattern Solder esist (in mm) Type BLM3 BLM5 BLM8 (except 8PG type) BLM2 (except 2PG type) BLM3 (except 3PG type) Soldering a eflow.2.3 eflow.4 Flow.7 eflow Flow/ eflow.2 2. b.6.9.2.4 2.22.6.82. 3.4. 4.25.2 BLM4 3. 5.56.5 (except 4Pp type) BLM3/5 is specially adapted for reflow soldering. Type BLM3 BLM4 a b c a 2. 3. a b e b 4.25.2 5.56.5 d.2.2 2.5 Pitch d.3.8 c.3.5.7..2 Flow Mounting in High Density for BLM3/4 c e.35.5 Type.5.5 a b BLM8PG 2 3.5 2 BLM2PG 3 6.5/2 BLM3PG 3 6 2 BLM4Pp 3 6 ated Current Soldering (A) Flow/ eflow a.7 b Flow 2.22.6 eflow.82..7.2 3.4.. 2. 4.25.2 3. 5.56.5 c.2 Land pad thickness and dimension d 8µm 35µm 7µm.7.2 2.4..2 2.4 6.4.2 2.4 6.4.2 2.4 6.4.7.7.2...2 3.3.2.2 3.3.2.2 3.3.7.7.7....65.2.2.65.2.2.65 odo not apply narrower pattern that listed above to BLMppP. Narrow pattern can cause excessive heat or open circuit. 6 BLA2A BLA3 oeflow soldering BLA2A.75 oeflow and Flow BLA3 2.8.5.5 2.22.6.8.5 Pitch.25.8 Pitch If there are high amounts of selfheating on pattern, the contact points of PCB and part may become damaged..4 34 Continued on the following page.
!Note C3E9.pdf 3.3.2 Continued from the preceding page. EMIFILr (Soldering and Mounting) Land Pattern + Solder esist Land Pattern Solder esist (in mm) NFM8 eflow Soldering NFM8C/NFM8P/NFL8ST NFL8SP Small diameter thru hole ø.3.4.6.2.8.8.4.2.4.6. 2.2 The chip EMI filter suppress noise by passing the highfrequency noise to ground. Therefore, to get noise suppression effectively, it is recommended to put through holes (ø.3 mm) into the center and both sides of groundpattern to connect to groundplane..4. 2. NFp8, NFp2 are specially adapted for reflow soldering. NFM2 NFM3D NFM4 NF2G NFL2S VFM4 o eflow Soldering Chip mounting side Small diameter thru hole ø.4ø.6 d Back side Ground pattern o Flow Soldering Chip mounting side Back side Small diameter thru hole ø.4ø.6 Ground pattern.6 e f g a b c Part Number NFM2C/NFM2P NF2G/NFL2S NFM3DC NFM3DP NFM4C NFM4P VFM4 a.8.4 2. 2. Connect to ground pattern of mounting side Size (mm) b.4 2.5 3.5 3.5 c 2.6 4.4 6. 6. d.6..2.2 Part Number NFM3DC NFM3DP NFM4C NFM4P VFM4 a b c d a..5.5 Connect to ground pattern of mounting side b.4 2. 2. Size (mm) c d e 2.5 3.5 3.5 4.4 6. 6...2.2 g f 2. 2.6 2.6 g 2.4 3. 3. NFA3G NFA3C NFW3S NFE3P o eflow Soldering NFA3G/3C 2.6.4. 2.2 o eflow and Flow NFW3S o eflow Soldering NFE3P Chip mounting side Small diameter thru hole ø.4ø.6 Back side Connect to ground pattern of mounting side 6. to.2 is preferred to obtain high voltage withstanding. 2.6 3. 3..3.8 Pitch 3.8.6.2 2.2 4.2 Ground pattern Continued on the following page. 35
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting) Continued from the preceding page. Land Pattern + Solder esist Land Pattern Solder esist (in mm) NFE6P NFE6H o eflow Soldering Chip mounting side Small diameter thru hole ø.4ø.6 Back side Connect to ground pattern of mounting side o Flow Soldering (Except NFE6H332) Chip mounting side Small diameter thru hole ø.4ø.6 Back side Connect to ground pattern of mounting side 2. 4.8 8.8 DLM2HG DLP3S DLP3D DLPS DLW2S DLW2H DLW3S DLW5AH DLW5BS oeflow and Flow DLM2HG DLP3S DLP3D..6. oeflow Soldering DLPS DLW2/DLW3S d c 2.6 2.6 3. 3..6.2 3.2 3.6 3.6 Ground pattern.5 3.8 4.8 9. Ground pattern 2..2.4 2..7.7 2.22.6.8 2.8. 4..8 pitch.4.55.85.3.55.95.3 3 a b DLW5AH/5BS Series DLW2S/H a.8 b 2.6 c.4 d.2 DLW3S.6 3.7.4.6 6.9 2.9 5.5.3 3.3 4.7 : If the pattern is made with wider than.2mm (DLW2) /.6mm (DLW3S) it may result in components turning around, because melting speed is different. In the worst case, short circuit between lines may occur. 2 : If the pattern is made with less than.4mm, in the worst case, short circuit between lines may occur due to spread of soldering paste or mount placing accuracy. 3 : If the pattern is made with wider than.8mm (DLW2) /.6mm (DLW3S), the bending strength will be reduced. With gild pattern, excess soldering heat may disolve metal of a copper wire. Continued on the following page. 36
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting) Continued from the preceding page. 2. Solder Paste Printing and Adhesive Application When reflow soldering the chip EMI suppression filter, the printing must be conducted in accordance with the following cream solder printing conditions. If too much solder is applied, the chip will be prone to damage by mechanical and thermal stress from the PCB and may crack. In contrast, if too little solder is applied, there is the potential that the termination strength will be insufficient, creating the potential for detachment. Standard land dimensions should be used for resist and copper foil patterns. When flow soldering the EMI suppression filter, apply the adhesive in accordance with the following conditions. If too much adhesive is applied, then it may overflow into the land or termination areas and yield poor solderability. In contrast, if insufficient adhesive is applied, or if the adhesive is not sufficiently hardened, then the chip may become detached during flow soldering process. (in mm) Series Solder Paste Printing Adhesive Application BLM BLA oensure that solder is applied smoothly to a minimum height of.2mm to.3mm at the end surface of the part. ocoat the solder paste a thickness: 5µm: BLM3 2µm: BLM5/8/2/3/4, BLA Coating amount is illustrated in the following diagram. Chip Solid Inductor a:2µm 7µm b:3µm 35µm c:5µm 5µm a c.2.3mm min PCB Bonding agent Land b NFM NF NFL VFM ouse H6A solder for pattern printing. ocoat the solder paste a thickness: 5µm: NFM8/2/3D,NF, NFL 2µm: NFM4,VFM Apply.mg for NFM4C/4P/VFM and.6mg for NFM3DC/3DP of bonding agent at each chip. Do not cover electrodes. NFM8C/8P NFL8ST NFL8SP NFM2C/2P NF2G/NFL2S.6.4 Bonding agent Coating position of bonding agent NFM3DC/3DP NFM4C/4P/VFM.8 2.. 2.6.6.6.6.6.9.4. 2.2 2.6. 2.5 3.9.5 3.5 5.5 NFA o Use H6A solder for pattern printing. ocoat the solder paste a thickness: 2µm NFA3G/NFA3C 2.6.6 2.2..4.4.6.2.4.2.4. 2. 6.3.8pitch Continued on the following page. 37
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting) Continued from the preceding page. (in mm) Series Solder Paste Printing Adhesive Application NFW3S NFE3P ouse H6A solder for pattern printing. ocoat the solder paste a thickness: 52µm NFW3S Series Apply.2mg of bonding agent at each chip...6 2.6.6 2.2 4.2 Bonding agent Coating positon of bonding agent NFE6P NFE6H ouse H6A solder for pattern printing. ocoat the solder paste a thickness: 52µm Apply.mg of bonding agent at each chip..6 2.6.2 3.2.6.5 4.8 8.8 Bonding agent.5 4.8 9. Bonding agent DLP DLW DLM ouse H6A solder for pattern printing. ocoat the solder paste a thickness: 5µm: DLW2S/2H/3S/DLPS 52µm: DLP3D/3S, DLM2HG, DLW5AH/5BS DLP3S/DLM2HG Apply.3mg of bonding agent at each chip. DLPS/3S DLW2S/DLW2H/DLW3S DLP3D DLP3S d c c Coating Position of Bonding Agent Coating Position of Bonding Agent DLM2HG DLP3D.4 Coating Position of Bonding Agent.8 DLW5AH/5BS..8. DLM2HG 5.5 2.9.9 2..2.4 a b a Series a b c d DLPS.7.55.3.55 DLP3S..6.7 2. a b Series DLW2S/H DLW3S a b c d.8 2.6.5.2.6 3.7.4.6 c d 6.3 3.3 4.7. 4. 38 Continued on the following page.
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting) Continued from the preceding page. 3. Standard Soldering Conditions () Soldering Methods Use flow and reflow soldering methods only. Use standard soldering conditions when soldering chip EMI suppression filters chip varistor. In cases where several different parts are soldered, each having different soldering conditions, use those conditions requiring the least heat and minimum time. (2) Soldering Temperature and Time To prevent external electrode solder leaching and performance deterioration, solder within the temperature and time combinations illustrated by the slanted lines in the following graphs. If soldering is repeated, please note that the allowed time is the accumulated time. Solder : H6A H63A solder(jis 3238) Flux : o Use osinbased flux (when using A type solder, clean products sufficiently to avoid residual flux. o Do not use strong acidic flux (with chlorine content exceeding.2wt%) o Do not use watersoluble flux. oallowable Flow Soldering Temperature and Time Temperature [ C] 28 27 26 25 24 23 5 5 2 25 3 Time [s] q NFE6P/H(Except NFE6HT332) w BLM(Except BLM3/5), BLA3 e DLM2HG, DLP3D/S r VFM4, NFM3DC/P, NFM4C/P, NFW3S oallowable eflow Soldering Temperature and Time 28 27 r e w q Temperature [ C] 26 25 24 23 r e w q 2 3 4 5 6 7 8 9 Time [s] q w e r NFE3P/NFE6P/H BLM/BLA DLM2HG, DLP3D/S, DLPS NFM, NFL, NFA, NF, HFW3S, DLW, VFM4 Continued on the following page. 6 39
!Note C3E9.pdf 3.3.2 EMIFILr (Soldering and Mounting) Continued from the preceding page. (3) Soldering Conditions oflow Solder Temperature [ C] 3 25 2 5 5 Preheating 6s Min. Soldering Max. Temp. 25 C T Gradual cooling (in air) Series Preheating (5 C) Soldering Time(T) Soldering Temp.(C) BLM(Except BLM3/5), BLA3 s max. NFM3DC/P, NFM4C/P, NFW3S, NFE6P/H*, DLM2HG, DLP3D/3S 6s min. 5s max. 25 VFM *Except NFE6HT332 (4) eworking with Solder Iron The following conditions must be strictly followed when using a soldering iron. Preheating : 5 C 6 s min. Soldering iron power output : 3W max. Temperature of soldering iron tip / Soldering time : 28 C max./s max. or 3 C max./3s max.* *NFE3PT52E9/VFM : 28 C max./ s max. only BLM : 35 C max./3 s max. Do not allow the tip of the soldering iron to directly contact the chip. For additional methods of reworking with to soldering iron, please contact Murata engineering. oeflow Solder Temperature [ C] Preheating 3 25 23 C 2 83 C 5 5 6s Min. NFE3/6 BLM, BLA NFM, NFL, NF NFW, NFA, DLM/P/W VFM Series Soldering Gradual cooling (in air) Max. Temp. 23 C T2 T Preheating Soldering Time (5 C) T(83 C) T2(23 C) 6s min. 6s max. 25 C,2s max. 2s max. s max. 6 4. Cleaning Following conditions should be observed when cleaning chip EMI filter. () Cleaning Temperature : 6 C max. (4 C max. for alcohol type cleaner) (2) Ultrasonic Output : 2W/liter max. Duration : 5 minutes max. Frequency : 28kHz to 4kHz (3) Cleaning agent The following list of cleaning agents have been tested on the individual components. Evaluation of final assembly should be completed prior to production. Do not clean DLW2S/3S/5AH/5BS series. In case of cleaning, please contact Murata engineering. a) Alcohol cleaning agent Isopropyl alcohol (IPA) b) Aqueous cleaning agent Surface active agent (Clean Thru 75H) Hydrocarbon (Cold Cleaner 375) High grade alcohol (Pine Alpha STS) *VFM4 series cannot be cleaned with high grade alcohol type aqueous cleaning agent. Alkaline saponifier (Aqua Cleaner 2SEIcleaner should be diluted within 5% using deionized water.) (4) Ensure that flux residue is completely removed. Component should be thoroughly dried after aqueous agent has been removed with deionized water. (5) Some products may become slightly whitened. However, product performance or usage is not affected. For additional cleaning methods, please contact Murata engineering. 4
!Note C3E9.pdf 3.3.2 Lead Type EMIFILr (Soldering and Mounting). Mounting Hole Mounting holes should be designed as specified below. DSN6 DSS6 VF3V VFS6V Part number Bulk type (in mm) Taping type (in mm) ø.83 2.5±.2 2.5±.2 DSN9 DSN9H ø.83.±.2 2.5±.2 2.5±.2 ø.3 DST9 DST9H ø.83.25±.2 2.5±.2 2.5±.2 2.5±.2 2.5±.2 DSS9 DSS9H VFS9V ø.83 2.5±.2 2.5±.2 2.5±.2 BN [Component Side] ø.2 (PSG) (B) (CG) (CG) (CG) (CB) 2.5±. 5.±. 7.5±. 2.5±. 2.5±. [TEMINAL LAYOUT (Bottom figure)] CB CG CG PSG : Power supply ground PSG B CG : Load circuit ground CB : Load circuit + Bias 2. Using THE block type EMIFILr effectively The block type EMIFILr effectively prevents unwanted reflections and external noise from entering the equipment circuitry and power lines by grounding all the high frequency components which make up the noise. Therefore, if grouding is improperly done, the filters may be unable to achieve the performance they are capable of. To prevent this, be sure to observe the following instructions. () When designing the P.C. board, use all the available grounding terminals, and arrange the grounding circuit so that the area of the foil for the grounding circuit is maximized. (2) Minimize the distance between the P.C. board ground and the filter's grounding plate. Use throughhole P.C. boards. (3) Whichever P.C. board is used, push the filter into the P.C. board up to the terminal roots. (4) Do not connect PSG to CG by any other means except through the filter. (See the item. TEMINAL LAYOUT) [P.C.B. BOAD PATTENS] Use a bilateral P.C. board. Insert the BN into the P.C.board until the root of the terminal is secured. then solder. () FONT VIEW (2) BOTTOM VIEW PSG PSG B B B PSG PSG CG CG CG CG CG CB CB CG B Shield plate PSG: Power supply ground CG : Load circuit ground CB : Load circuit + Bias Continued on the following page. 4 6
!Note C3E9.pdf 3.3.2 Lead Type EMIFILr (Soldering and Mounting) Continued from the preceding page. 3. Using EMIGUADr effectively () Terminal (with mark) should be connected to the line of incoming electrostatic surge. (There is polarity.) Otherwise, no effect in ESD suppression can be expected. (VF3V) (2) Products should be used at rated voltage or less and rated current or less. (3) Products should not be applied for the absorption of surges which have large energy (ex. induced lightning surges, switching surges) because it is designed for the absorption of electrostatic surges. (VF3V) (4) Electrostatic test should be done on the following conditions. (VF3V) n [ C / V 2 ] 2 < 8. 5 n : Times applies C : Charging Capacitance (pf) V : Testing Voltage (kv) : Charging esistance (Ω) Example of input terminal incoming Electrostatic Surges Example of output terminal incoming Electrostatic Surges 4. Soldering () Use osinbased flux. Do not use strong acidic flux with halide content exceeding.2 (wt)% (chlorine conversion value). (2) Standard flow soldering profile. (3) Products and the leads should not be subjected to any mechanical stress during the soldering process, or while subjected to the equivalent high temperatures. [Flow Soldering] Temperature ( C) Preheating (in air) 3 25 2 5 5 Gradual cooling Soldering (in air) 24 to 26 C minutes min. 5s. max. Preheating Solder Temperature 5 C, 6 seconds min. 24 26 C, 5 seconds within 6 5. Cleaning Conditions Do not clean VF3V, PLT9H and VFS6Vseries. Clean other parts in the following conditions. () Cleaning temperature should be limited to 6 C max.(4 C max for alcohol type cleaner.) (2) Ultrasonic cleaning should be comply with the following conditions, avoiding the resonance phenomenon at the mounted products and P.C.B. Power : 2 W / l max. Frequency : 28kHz to 4kHz Time : 5 min. max. (3) Cleaner a) Alcohol type cleaner Isopropyl alcohol (IPA) b) Aqueous agent (PLT series cannot be cleaned) Surface Active Agent Type (CLEANTHOUGH 75H) Hydrocarbon Type (COLDCLEANE 375) Higher Alcohol Type (PINE ALPHA STS) Alkali Saponification Type (*AQUACLEANE 2SEI) * Alkali saponification should be diluted to 5% volume with deionized water. (4) There should be no residual flux or residual cleaner after cleaning. In the case of using aqueous agent, products should be dried completely after rinsing with deionized water in order to remove the cleaner. (5) Other cleaning : Please contact us. 42 2
!Note C3E9.pdf 3.3.2 Chip EMIFILr Packaging Minimum Quantity and Dimensions of 8mm Width Paper / Plastic Tape 2 2.±. 4.±. 4.±. +. ø.5.75±. <plastic> c d <paper> a 3 3.5±. 8.±.3 b Direction of feed There are holes in the cavities of the BLM2BD222SN/ BD272SN and BLM3 only. ø. +.3 c BLM5, BLA2A: 2.±. 2 NFE3, NFW3, DLPS: 2.±.5 3 NFE3, NFW3, DLPS: 3.5±.5 Part Number BLM3 BLM5 BLM8 (BLM8E_TN) a.7.5.85 Cavity Size b c.4.55.65.8..5.75 d Minimum Qty. (pcs.) ø8mm reel ø33mm reel Paper Tape Plastic Tape Paper Tape Plastic Tape 5 5 4 Bulk BLM2 (BD222SN/BD272SN) 2.25.45..3.2 4 3 BLM3 (AF7SN) 3.5.9.3.75.2 3 25 8 BLA2A 2.2.2.8 BLA3 3.4.8. 4 NFM8/NFL8S NFM8PC (Except 5).85.5.9 4 5 NFL8ST/NFM8PC5. 4 5 NFM2/NFL2S 2.3.55. 4 5 NFM3DC/3DP 3.4.4.85.2 4 5 NFA3G/3C 3.5 2.. 4 NFE3P 3.6.9 2..2 2 8 5 NF2G 2.3.55.7.25 4 5 NFW3S 3.6.9 2..2 2 75 DLM2HG 2.75 2.25.3.25 3 DLPS.4.2.98.25 3 5 DLP3D/3S 3.5.9.3.25 3 5 DLW2S 2.25.45.4.3 2 5 DLW2H 2.3.55..25 3 5 DLW3S 3.6 2. 2..3 2 5 Please contact us for BLM5/8 in bulk case. (in mm) Continued on the following page. 6 43
!Note C3E9.pdf 3.3.2 Chip EMIFILr Packaging Continued from the preceding page. Minimum Quantity and Dimensions of 2mm Width Plastic Tape 2.±. 4.±. 4.±. a There are holes in the cavities of the BLM4 only. ø.5 +.3 b +. ø.5.75±. 5.5±. 2.±.3.3 Direction of feed c Part Number BLM4 NFM4 NFE6 VFM4 Cavity Size a b 4.8.9 4.8.8 7.2.9 4.8.8 c.75..75.35 ø8mm reel 25 4 25 25 Minimum Qty. (pcs.) ø33mm reel 8 8 Bulk 5 5 5 8.±. 2.±. 4.±. ø.5 +..75±..3 c Part Number Cavity Size a b c Minimum Qty. (pcs.) ø8mm reel ø33mm reel Bulk a 5.5±. 2.±.3 DLW5AH DLW5BS 5.4 5.5 4. 5.4 4.4 4.7 4 4 5 5 ø.5 +.3 b Direction of feed (in mm) 6 44
t I Minimum Quantity (Pcs.) Series Bulk Ammo Pack BLN BL2N BL3N 5 5 5 2 ø32mm Paper reel 2 BLN max. Direction of feed t ø3.6 ±.5 5±.3.8 max. L L2 ø.6 5±.5.2 max. 3.2 min.8 max. BL2N2pA W W L P P2 F P 7.5 max. 7.5 max. W2 H W 3.4±.2 ød S h h2 *L 6.±. L L2 V.5 *L BLNAFJ : 52+2/ BLNAEA : 26+.5/ D P There is a excess bond stick on the wire. BL2N3NA P 2. max. W2 H 3.4±.2 ød S h h2 BL2N2pA W W W I P P2 F 8. max. L t P 7.5 max. W2 H 3.4±.2 ød S h h2 W W W I P P2 F 9. max. L t BL2N23NA D P There is a excess bond stick on the wire. BL3N2pA P D S P 9. max. 3.4±.2 2. max. W2 H ød h h2 W W W I P2 P F L t S P 8.3 max. 2.3 max. 6.5 max. W2 H ød h h2 W W W I!Note C3E9.pdf 3.3.2 Ferrite Beads Inductors Packaging Taping Dimensions P2 P F L P D P D Description Symbol Dimension (mm) emarks Pitch of component P 2.7 Product inclination S determines tolerance Pitch of sprocket hole Lead spacing Hole center to lead P F P 2.7±.2 +.8 5..2 3.85±.7 Hole center to component center P2 6.35±.3 Tape deviation in feeding direction Deviation along tape, left or right S ±. Carrier tape width Position of sprocket hole Lead length between sprocket hole and forming position W W H 8.±.5 + 9..5. Lead Length Number : N Lead Length Number : Q Lead Length Number : P 6.5±.5 2.±.5 8.5±.5 Tape with deviation BL2, BL3 BL2N***PA BL3N 6 Protruding length I +.5 to. Diameter of sprocket hole D ø4.±. Lead Diameter ød ø.6 Total tape thickness t.7±.2 Including bonding tape thickness Deviation across tape, Deviation across tape rear Cutting position of failure Hold down tape width h, h2 L W. max. +... 2.±.5 Hold down tape position W2.5±.5 (in mm) 45
!Note C3E9.pdf 3.3.2 Disc Type EMIFILr and EMIGUADr Packaging Minimum Quantity Lead Type Code Part Number VF3V Series DS 6/VFS6V Series DSN9/9H Series DST9/9H Series DSS9/9H Series VFS9V Series Minimum Order Quantity (order in sets only) (Pcs.) Ammo Pack ø32mm Paper reel Bulk (Bag) 2 25 2 25 2 25 2 2 8 2 8 2 Straight Type Q9 Q92 Q93 Lead Type code Incrimp Type U2 U3 Lead length (H) 2.±.mm 6.5±.mm 8.5±.mm : Q92, Q93 2 : Q9 Taping Dimensions DSN6_Q9/Q92/Q93 DSS6_Q9/Q92/Q93 DSN9_Q9/Q92/Q93 DSN6_ : 7. max. DSN9_ : 9.5 max. 5.+.8/.2 2.5+.4/.2 6.35±.3 2.7 ±. 3.85±.7.+/..5±.5 8.±.5 9.+/.5 DSN6_ : 8. max. DSN9_ :. max. H 2.±.5 DSN6_ : 2.54 max. DSN9_ : 4. max.. max.. max. ø.6 *2.+/. 3.85±.7 8.±.5 9.+/.5 5.+.8/.2 2.5+.4/.2 6.35±.3 2.7 8. max. ±. *.5±.5 2.5+.4/.2 7. max. H 2.54 max.. max.. max. ø.6 2.±.5 H Q9 Type : 2±. Q92 Type : 6.5±. Q93 Type : 8.5±. 2.7±.2 ø4.±..7±.2 +.5 to..5 max. H Q9 Type : 2±. Q92 Type : 6.5±. Q93 Type : 8.5±. 2.7±.2 ø4.±..7±.2 +.5 to. * There may be a hole on the top of ferrite beads, which cause no characteristics deterioration. *2 Bottom of the ferrite beads may not be level with each other..5 max. DST9_Q9/Q92/Q93 DSS6_U2/U3 VFS6V_U3 8.±.5 5.+.8/.2 2.5+.4/.2 6.35±.3 2.7 9.5 max. ±. 3.85±.7.+/. 9.+/.5 2.5+.4/.2.5±.5 5.5 max. H 4. max.. max.. max. 2.±.5 ø.6 *2 3.85±.7.+/. 8.±.5 9.+/.5 5.+.8/.2 2.5+.4/.2 6.35±.3 2.7 8. max ±. * 2.5+.4/.2.5±.5 H DSS6_U :. max. VFS6V :.5 max. 2.±.5 2.54 max.. max.. max. ø.6 H Q9 Type : 2±. Q92 Type : 6.5±. Q93 Type : 8.5±. 2.7±.2 ø4.±..7±.2 +.5 to..5 max. H U2 Type : 6.5±. U3 Type : 8.5±. 2.7±.2 ø4.±..7±.2 +.5 to. * There may be a hole on the top of ferrite beads, which cause no characteristics deterioration. *2 Bottom of the ferrite beads may not be level with each other..5 max. 6 DSS9_Q9/Q92/Q93 VFS9V_Q9/Q92/Q93 *.+/. 3.85±.7 8.±.5 9.+/.5 H Q9 Type : 2±. Q92 Type : 6.5±. Q93 Type : 8.5±. 6.35±.3 2.7 2.7±.2 5.+.8/.2 2. max. ±. 2.5+.4/.2 ø4.±. 2.5+.4/.2.5±.5.7±.2. max. H 2.±.5 +.5 to. * Bottom of the ferrite beads may not be level with each other. 7.5 max.. max.. max. ø.6.5 max. VF3V_U3 3.85±.7.+/. 8.±.5.5 max. 9.+/.5 5.+.8/.2 2.5+.4/.2 2.3 max. 6.35±.3 2.7 8. max. ±. AY AY AY.5±.5 2.5+.4/.2 8.5±. 5. max. ()(2)(3) +.5 to. 2.7±.2 ø4.±.. max.. max. ø.45±. 2.±.5.7±.2 (in mm) 46
!Note C3E9.pdf 3.3.2 Chip EMI Suppression Filter Design Kits oekembl5c (Chip Ferrite Beads 42 Size) No. Part Number Quantity (pcs.) Impedance typ. (at MHz, 2 degree C) ated Current (ma) DC esistance (Ω) max. BLM5AGSN 2 Ω (Typ.).5 2 BLM5AG7SN 2 7Ω (Typ.) 5.5 3 BLM5AG2SN 2 2Ω±25% 5.25 4 BLM5AG22SN 2 22Ω±25% 3.35 5 BLM5AG6SN 2 6Ω±25% 3.6 6 BLM5AG2SN 2 Ω±25% 2. 7 BLM5BB5SN 2 5Ω±25% 5.8 8 BLM5BBSN 2 Ω±25% 3. 9 BLM5BB22SN 2 22Ω±25% 3.2 BLM5BB47SN 2 47Ω±25% 3.35 BLM5BB75SN 2 75Ω±25% 3.4 2 BLM5BB2SN 2 2Ω±25% 3.55 3 BLM5BB22SN 2 22Ω±25% 2.8 4 BLM5BD47SN 2 47Ω±25% 2.6 5 BLM5BD6SN 2 6Ω±25% 2.65 6 BLM5BD2SN 2 Ω±25% 2.9 oekembl8a (Chip Ferrite Beads 63 Size/ for Largecurrent P Type) No. Part Number Quantity (pcs.) Impedance typ. (at MHz, 2 degree C) ated Current (ma) DC esistance (Ω) max. BLM8AG2SN 2 2Ω±25% 2.2 2 BLM8AG22SN 2 22Ω±25% 2.3 3 BLM8AG47SN 2 47Ω±25% 2.5 4 BLM8AG6SN 2 6Ω±25% 2.5 5 BLM8AG2SN 2 Ω±25%.7 6 7 8 BLM8BA5SN BLM8BASN BLM8BA22SN 2 2 2 5Ω±25% Ω±25% 22Ω±25% 5 5 5.2.25.35 6 9 BLM8BA47SN 2 47Ω±25% 3.55 BLM8BA75SN 2 75Ω±25% 3.35 BLM8BA2SN 2 2Ω±25% 2.9 2 BLM8BBSN 2 Ω±25% 5.5 3 BLM8BB22SN 2 22Ω±25% 5.25 4 BLM8BB47SN 2 47Ω±25% 5.3 5 BLM8BB6SN 2 6Ω±25% 2.35 6 BLM8BB2SN 2 2Ω±25% 2.5 7 BLM8BB22SN 2 22Ω±25% 2.65 8 BLM8BB47SN 2 47Ω±25% 5. 9 BLM8BD2SN 2 2Ω±25% 2.4 Continued on the following page. 47
!Note C3E9.pdf 3.3.2 Chip EMI Suppression Filter Design Kits Continued from the preceding page. No. Part Number Quantity (pcs.) Impedance typ. (at MHz, 2 degree C) ated Current (ma) DC esistance (Ω) max. 2 2 22 23 24 25 26 27 28 29 3 3 32 33 34 35 36 37 38 39 4 4 42 43 44 45 46 47 48 49 5 BLM8BD22SN BLM8BD47SN BLM8BD6SN BLM8BD2SN BLM8BD82SN BLM8BD252SN BLM8HG47SN BLM8HG6SN BLM8HG2SN BLM8HD47SN BLM8HD6SN BLM8HD2SN BLM8PG33SN BLM8PG2SN BLM8PG8SN BLM2PG22SN BLM2PG33SN BLM3PG2SN BLM3PG39SN BLM3PG6SN BLM4PG8SN BLM4PG47SN BLM4PG2SN BLM8K2SN BLM8K22SN BLM8K47SN BLM8K6SN BLM8K2SN BLM8HK47SN BLM8HK6SN BLM8HK2SN 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 22Ω±25% 47Ω±25% 6Ω±25% Ω±25% 8Ω±25% 25Ω±25% 47Ω±25% 6Ω±25% Ω±25% 47Ω±25% 6Ω±25% Ω±25% 33Ω±25% 2Ω±25% 8Ω±25% 22Ω (Typ.) 33Ω (Typ.) 2Ω (Typ.) 39Ω (Typ.) 6Ω (Typ.) 8Ω (Typ.) 47Ω (Typ.) Ω (Typ.) 2Ω±25% 22Ω±25% 47Ω±25% 6Ω±25% Ω±25% 47Ω±25% 6Ω±25% Ω±25% 2 2 2 5 5 2 2 5 3 2 5 2 5 3 2 5 3 2 5 2 2 2 2 2 2 5.45.55.65.85.5.5.85..6.2.5.8.25.5.9.5.9.25.5.9.25.5.9.25.3.5.6.8.7.9.5 oekembl2a (Chip Ferrite Beads 85 Size) No. Part Number Quantity (pcs.) Impedance typ. (at MHz, 2 degree C) ated Current (ma) DC esistance (Ω) max. BLM2AG2SN 2 2Ω±25% 2.5 2 BLM2AG22SN 2 22Ω±25% 2.2 3 BLM2AG47SN 2 47Ω±25% 2.25 6 4 5 6 BLM2AG6SN BLM2AJ6SN BLM2AG2SN 2 2 2 6Ω±25% 6Ω±25% Ω±25% 2 2 2.3..45 7 BLM2AH2SN 2 Ω±25% 2.45 8 BLM2BB6SN 2 6Ω±25% 2.2 9 BLM2BB75SN 2 75Ω±25% 2.25 BLM2BB2SN 2 2Ω±25% 2.25 BLM2BB22SN 2 22Ω±25% 2.35 2 BLM2BB47SN 2 47Ω±25% 2.45 3 BLM2BD2SN 2 2Ω±25% 2.25 4 BLM2BD22SN 2 22Ω±25% 2.25 5 BLM2BD47SN 2 47Ω±25% 2.35 6 BLM2BD6SN 2 6Ω±25% 2.35 7 BLM2BD2SN 2 Ω±25% 2.4 Continued on the following page. 48 2
!Note C3E9.pdf 3.3.2 Continued from the preceding page. Chip EMI Suppression Filter Design Kits No. Part Number Quantity (pcs.) Impedance typ. (at MHz, 2 degree C) ated Current (ma) DC esistance (Ω) max. 8 BLM2BD82SN 2 8Ω±25% 2.5 9 BLM2BD222SN 2 225Ω (Typ.) 2.6 2 BLM2BD222TN 2 22Ω±25% 2.6 2 BLM2BD272SN 2 27Ω±25% 2.8 oekemfl8b (Chip EMIFIL LC Combined Type) No. Part Number Quantity (pcs.) Cut off Frequency ated Voltage ated Current NFL8ST7C3 2 MHz 6 V ma 2 NFL8ST57C3 2 5MHz 6 V ma 3 NFL8ST27C3 2 2MHz 6 V 5mA 4 NFL8ST37C3 2 3MHz 6 V 2mA 5 NFL8ST57C3 2 5MHz 6 V 2mA 6 NFL8SP57A3 2 5MHz V ma 7 NFL8SP27A3 2 2MHz V ma 8 NFL8SP37A3 2 3MHz V ma 9 NFL8SP57A3 2 5MHz V ma NFL2SP26C3 2 2MHz 6 V ma NFL2SP56C3 2 5MHz 6 V 5mA 2 NFL2SP76C3 2 7MHz 6 V 5mA 3 NFL2SP7C3 2 MHz 6 V 2mA 4 NFL2SP57C3 2 5MHz 6 V 2mA 5 NFL2SP27C3 2 2MHz 6 V 25mA 6 NFL2SP37C3 2 3MHz 6 V 3mA 7 NFL2SP47C3 2 4MHz 6 V 3mA 8 NFL2SP57C3 2 5MHz 6 V 3mA Insulation esistance (MΩ min.) DC esistance max. 4.5Ω 4.Ω 3.5Ω.8Ω.5Ω 3.Ω 3.Ω 3.Ω 2.Ω 8.5Ω 3.5Ω 3.Ω 2.Ω 2.Ω.5Ω.2Ω.2Ω.2Ω No. Part Number Quantity (pcs.) Cut off Frequency Attenuation (db min.) MHz 2MHz 5MHz MHz 5MHz 2MHz 3MHz 4MHz 5MHz GHz ated ated Current Voltage 9 NFW3SP6E4 2 MHz 6dB max 5 25 25 25 3 3 2mA 25V 2 NFW3SP26E4 2 2MHz 6dB max 5 25 25 3 3 2mA 25V 2 NFW3SP56E4 2 5MHz 6dB max 3 3 3 2mA 25V 22 NFW3SP7E4 2 MHz 6dB max 5 2 3 2mA 25V 23 NFW3SP57E4 2 5MHz 6dB max 2 3 3 2mA 25V 24 NFW3SP27E4 2 2MHz 6dB max 3 2mA 25V 25 NFW3SP37E4 2 3MHz 6dB max 5 5 2mA 25V 26 NFW3SP47E4 2 4MHz 6dB max 2mA 25V 27 NFW3SP57E4 2 5MHz 6dB max 2mA 25V oekemfa3b (Chip EMIFIL Capacitor Array Type/ Capacitor Type/ LC Combined Type) 6 No. Part Number Quantity (pcs.) Capacitance ated Voltage ated Current Insulation esistance (MΩ min.) NFA3CC22SE4 2 22pF±2% 25 V 2mA 2 NFA3CC47SE4 2 47pF±2% 25 V 2mA 3 NFA3CCSE4 2 pf±2% 25 V 2mA 4 NFA3CC22SE4 2 22pF±2% 25 V 2mA 5 NFA3CC47E4 2 47pF±2% 25 V 2mA 6 NFA3CC2E4 2 pf±2% 25 V 2mA 7 NFA3CC222E4 2 22pF±2% 25 V 2mA 8 NFA3CC223C4 2 22pF±2% 6 V 2mA 9 NFA3GD684 2 pf±2% 6 V 5mA NFA3GD474 2 pf±2% 6 V 2mA 5 Continued on the following page. 493
!Note C3E9.pdf 3.3.2 Chip EMI Suppression Filter Design Kits Continued from the preceding page. oekemfa3b (Chip EMIFIL Capacitor Array Type/ Capacitor Type/ LC Combined Type) No. Part Number Quantity (pcs.) Capacitance ated Voltage ated Current Insulation esistance (MΩ min.) 2 3 4 5 6 7 NFA3GD4 NFA3GD47684 NFA3GD47474 NFA3GD474 MFA3GD684 NFA3GD474 NFA3GD4 2 2 2 2 2 2 2 pf±2% 47pF±2% 47pF±2% 47pF±2% pf±2% pf±2% pf±2% 6 V 6 V 6 V 6 V 6 V 6 V 6 V 5mA 5mA 2mA 5mA 5mA 2mA 5mA oekemdl2c (Chip Common Mode Choke Coils) No. Part Number Quantity (pcs.) Common Mode Impedance typ. (at MHz, 2 degree C) ated Voltage ated Current Insulation esistance (MΩ min.) 2 3 4 5 6 7 8 9 2 3 4 5 6 7 8 9 2 2 22 23 DLW2SN67SQ2 DLW2SN9SQ2 DLW2SN2SQ2 DLW2SN8SQ2 DLW2SN26SQ2 DLW2SN37SQ2 DLW3SN9SQ2 DLW3SN6SQ2 DLW3SN26SQ2 DLW3SN6SQ2 DLW3SN2SQ2 DLW3SN222SQ2 DLW5AHN42SQ2 DLW5BSN32SQ2 DLW5BSN52SQ2 DLW5BSN2SQ2 DLW5BSN35SQ2 DLW5BSN9SQ2 DLP3DN9ML4 DLP3DN3ML4 DLP3DN2ML4 DLP3DN32ML4 DLP3DN44ML4 5 5 5 5 5 5 67Ω (Typ.) 9Ω (Typ.) 2Ω (Typ.) 8Ω (Typ.) 26Ω (Typ.) 37Ω (Typ.) 9Ω (Typ.) 6Ω (Typ.) 26Ω (Typ.) 6Ω (Typ.) Ω (Typ.) 22Ω (Typ.) 4Ω (Typ.) 3Ω (Typ.) 5Ω (Typ.) Ω (Typ.) 35Ω (Typ.) 9Ω (Typ.) 9Ω±2% 3Ω±2% 2Ω±2% 32Ω±2% 44Ω±2% 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V 5V V V V V V 4mA 33mA 37mA 33mA 3mA 28mA 37mA 34mA 3mA 26mA 23mA 2mA 2mA 5mA ma 5mA 2mA 5mA 6mA 2mA ma 8mA 7mA oekemnfmpa 6 No. Part Number Quantity (pcs.) Capacitance ated Voltage ated Current Insulation esistance (MΩ min.) 2 3 4 5 6 7 8 9 2 NFM8PC4C3 NFM8PC5J3 NFM2PC4E3 NFM2PC224C3 NFM2PC474C3 NFM2PC5BA3 NFM2PC5FC3 NFE3PT52E9 NFE3PT222E9 NFE6PT2EH9 NFE6PT472CH9 NFM4PC24FH3 2 2 2 2 2 2 2 2 2 2 2 2.µF±2% µf±2%.µf±2%.22µf±2%.47µf±2% µf±2% µf +8/2% 5pF +5/2% 22pF±5% pf +8/2% 47pF +8/2%.2µF +8/2% 6 V 6.3 V 25 V 6 V 6 V V 6 V 25 V 25 V 5 V 5 V 5 V 2A 2A 2A 2A 2A 4A 2A 6A 6A 2A 2A 2A 5 5 5 Continued on the following page. 5 4
!Note C3E9.pdf 3.3.2 Continued from the preceding page. oekemnfmca Chip EMI Suppression Filter Design Kits No. Part Number Quantity (pcs.) Capacitance ated Voltage ated Current Insulation esistance (MΩ min.) 2 3 4 5 6 7 NFM8CC22UC3 NFM8CC47UC3 NFM8CCC3 NFM8CC22C3 NFM8CC47C3 NFM8CC2C3 NFM8CC222C3 2 2 2 2 2 2 2 22pF±2% 47pF±2% pf±2% 22pF±2% 47pF±2% pf±2% 22pF±2% 6 V 6 V 6 V 6 V 6 V 6 V 6 V 3mA 3mA 3mA 3mA 3mA 3mA 3mA 8 9 2 3 4 5 6 NFM8CC223C3 NFM2CC22UH3 NFM2CC47UH3 NFM2CCUH3 NFM2CC22H3 NFM2CC47H3 NFM2CC2H3 NFM2CC222H3 NFM2CC223H3 2 2 2 2 2 2 2 2 2 22pF±2% 22pF±2% 47pF±2% pf±2% 22pF±2% 47pF±2% pf±2% 22pF±2% 22pF±2% 6 V 5 V 5 V 5 V 5 V 5 V 5 V 5 V 5 V ma 3mA 3mA 3mA 3mA 3mA 3mA 3mA 2mA 6 55
!Note C3E9.pdf 3.3.2 Outlines of Major Noise egulation Standards. EMI egulations Equipment Countries Information egulation Japan USA Europe CISP663 EN58 (esidential, Commercial (esidential, Commercial Generic Standard and Light Industry) and Light Industry) IEC664 EN582 (Industrial) (Industrial) ITE : Information Technology Equipment Printer, Personal computer CISP 22 VCCI FCC Part 5 Subpart B EN5522 Word processor, Display ISM equipment, Microwave CISP FCC Part 8 EN55 Emission Igniter (Automobile, Motorboat) TV, adio, Audio, VT CISP 2 CISP 3 JASO FCC Part 5 Subpart B FCC Part 5 Subpart B Automotive Directive EN553 Household electrical equipment CISP 4 EN554 Portable tool Fluorescent Lamp, Luminary CISP 5 EN555 adio Act FCC Part 5 Transceiver ITUT AIB Subpart C ETS3 Series (Voluntary agulation) FCC Part 22 (eference) Power Supply Higher Harmonic IEC63 Industrial Voluntary egulation EN63 Basic Standard IEC64 In the process of egulating at JIS EN64 Series IEC66 EN582 Immunity Generic Standard Industrial Process Measurement (esidential, Commercial and Light Industry) IEC662 (Industrial) In the process of egulating at JIS (esidential, Commercial and Light Industry) EN5822 (Industrial) and Control Equipment adio, TV CISP 2 Industrial Voluntary Action EN552 ITE : Information Technology Equipment CISP 24 EN5524 Electrical Appliance and Material Safety Law There are EMI regulations in each country to meet EMI noise levels emitted from digital equipment. In the countries which regulate EMI, equipment which does not satisfy with regulations is not allowed to be sold. 52 Continued on the following page.
!Note C3E9.pdf 3.3.2 egulation CISP 22/ EN5522 VCCI Continued from the preceding page. 2. Measurement Point and Noise Detection FCC Part 5 Outlines of Major Noise egulation Standards Measuring Item Polarization and Measuring Point Frequency (Hz) Detection Measuring Devices adiated Interference Horizontal Pol. Vertical Pol. 3M to GHz QuasiPeak Detection Antenna Main Interference Voltage adiated Interference Main Interference Voltage adiated Interference Main Interference Voltage AC Main Ports Horizontal Pol. Vertical Pol. AC Main Ports Horizontal Pol. Vertical Pol. AC Main Ports 5k to 3MHz 3M to GHz 5k to 3MHz 3M to 4GHz 5k to 3MHz QuasiPeak Detection Mean Detection QuasiPeak Detection QuasiPeak Detection Mean Detection QuasiPeak Detection Mean Detection QuasiPeak Detection Artificial Main Network Dipole Antenna Artificial Main Network Antenna Artificial Main Network PeakUQuasiPeakUAverage (Qp) V Peak Detection QuasiPeak Detection V Peak Detection Average Detection QuasiPeak Detection Average Detection t t Short epetition Period Long epetition Period 3. Limits of CISP 22/EN5522 ()CISP 22 recommends measurement at m distance. However, other distance is acceptable if the limitation is converted according to the following calculation. Limitation shown left is converted to limitation for 3m Limitation for m Distance (db µ V/m) r (µ V/m) Conversion Limitation for 3m Distance 3 (db µ V/m) r3 (µ V/m) =2 log r 3=2 log r3 3=+2 (log3) r3 = r 3 [Main Terminal Interference Voltage (Power Supply)] 9 Voltage [dbµv] 79 class A Quasipeak value 73 7 66 class A Mean value 6 56 5 56 class B Quasipeak value 5 46 class B Mean value 3 k k 5k 5k M 5M M 3M M Frequency [Hz] [adiated Interference] 9 Field Strength [dbµv/m] 7 5 5 4 class A class B 57 47 3 M 3M M 23M G Frequency [Hz] On the border frequency, lower limit should be applied. Class A Equipment : The equipment which is used in light industrial commercial areas. Class B Equipment : The equipment which is used in residential areas. Continued on the following page. 53
!Note C3E9.pdf 3.3.2 Outlines of Major Noise egulation Standards Continued from the preceding page. (2)Scope of CISP 22 egulation This regulation applies to information technology equipment (ITE) which are defined as: (a) Equipment that receives data from external signal sources; (b) Equipment that processes received data; (c) Equipment that outputs data (d) Equipment that has less than 6V rated voltage in power supply [CISP egulations] CISP Organization, egulations and Procedures of CISP CISP Industrial, Scientific and Medical (ISM) adiofrequency Equipment CISP 2 Vehicles, Motor Boats and SparkIgnited Engine driven CISP 3 Sound and Television eceivers CISP 4 Household Electrical Appliances, Portable Tools and Similar Electrical Apparatus CISP 5 Fluorescent Lamps and Iuminaries CISP 6 adio Interference Measuring Apparatus and Measurement Methods CISP 7 Passive adio Interference Filters and Suppression Components CISP 8 Power Transmission Cables and High Voltage equipment CISP 9 Microwave Ovens for Frequencies above GHz CISP 2 Immunity of Sound and TV Broadcast eceivers Veceivers and Associated Equipment CISP 2 Interference to Mobile adiocommunications in the Presence of Impulsive Noise CISP 22 Information Technology Equipment CISP 23 Industrial Scientific and Medical (ISM) Equipment CISP 24 Immunity egulation of Information Technology Equipment CISP 25 eceiver used on board vehicles, boats, and on devices 4. Limits of VCCI Voluntary egulation ()VCCI recommend measurement at m distance. 3m or 3m distance measurement are also allowed. [Main Terminal Interference Voltage (Power Supply)] (2)Scope of VCCI Voluntary egulation This regulation applies to information technology equipment (same as CISP Pub.22), but the application is excluded on the following equipment: Equipment for which other regulations already exist (e.g., household electrical appliances, radio and TV receivers) In station equipment principal purpose of which is electrical communication Industrial plant control system for which information processing is a secondary system function Industrial, commercial and medical testing and measuring systems for which data processing is a secondary system function Information equipment for which CISP is conducting further deliberation VCCI is the acronym of Voluntary Control Council for Interference by Data Processing Equipment and Electronic Office Machines. VCCI is organized by the following organizations: Japan Electronics and Information Technology Industries Association (JEITA) Japan Business Machine and Information System Industries Association (JBMIA) Communication and Information network Association of Japan (CIAJ) Voltage [dbµv] 9 7 5 79 66 56 56 46 class A Quasipeak value class B Mean value 3 k k 5k 5k M 5M M 3M M [adiated Interference] Field Strength [dbµv/m] 9 7 5 5 Frequency [Hz] 4 class B Quasipeak value On the border frequency, lower limit should be applied. Class B ITE : Equipment that designed to be used at home. Class A ITE : Equipment that does not meet interference limits of class B equipment, but satisfies interference limits of class A equipment. 73 class A Mean value 6 class B Quasipeak value 5 class A Quasipeak value 3 M 3M M 23M G Frequency [Hz] 57 47 Continued on the following page. 54
!Note C3E9.pdf 3.3.2 Outlines of Major Noise egulation Standards Continued from the preceding page. 5. Limits of FCC Part 5 Subpart B ()Class A recommend to be measured with m distance. Class B recommend to be measured with 3m distance. (2)The FCC Part 5 regulation controls radiated interference by establishing quasipeak and mean value limits for frequencies ranging from 3MHz to 4GHz (or maximum frequency's fifth harmonic, whichever is lower). For AC main ports, the FCC Part 5 regulation controls main terminal interference voltage by establishing quasipeak value limits for frequencies ranging from 45kHz to 3MHz. Measurement Frequency ange for adiated Interference Maximum Frequency the Equipment Internally Generates, Uses or Operates or Synchronizes (MHz) Less than.75.75 to 8 8 to 5 5 to Over Upper End of Measurement Frequency ange (MHz) 3 2 5 Maximum Frequency's Fifth Harmonic or 4GHz, Whichever is Lower [Main Terminal Interference Voltage (Power Supply)] Voltage [dbµv] [adiated Interference] Field Strength [dbµv/m] 9 7 5 9 7 5 79 66 56 49.5 54 4 56 46 3 k k 5k 5k M 5M M 3M M Noise level is regulated up to lower frequency of the 5th harmonics of maximum signal frequency and 4GHz. 43.5 class A Quasipeak value 56.9 46 6 class A 54 class B 73 class A Mean value 6 class B Quasipeak value 5 class B Mean value Frequency [Hz] 3 M 3M 88MM 26M 96MG Frequency [Hz] On the border frequency, lower limit should be applied. Class A Equipment : The digital equipment that is sold to in the commercial, industrial and office use. Class B Equipment : The digital equipment that is sold to be used in residential area. (3)There is no regulation on power interference. [FCC egulations] Part Part 2 Procedures Frequency Division and adio Wave Treaty Issues and General ules Part 5 adio Wave Equipment Intentionally electromagnetic radiation equipment Nonintentionally electromagnetic radiation equipment Incidentally electromagnetic radiation equipment Part 8 Industrial, Scientific and Medical Equipment Part 22 Public Mobile Wireless Operations Part 68 Connecting Terminal Equipment to Telephone Circuit Network Part 76 Cable Television Continued on the following page. 55
!Note C3E9.pdf 3.3.2 Outlines of Major Noise egulation Standards Continued from the preceding page. 6. Immunity egulations in Europe Union All electric/electronic equipment cannot be sold in Europe without CE marking. To use CE marking, they must satisfy related EC directives such as EMC directives. For Information Technology Equipment, in EMC directive, emission regulations are integrated, and immunity regulations are applied. Although these immunity regulations are prepared by CENELEC, almost all contents are same as standards issued by IEC or CISP. All products which are sold in EU must satisfy EC directive which contains immunity regulation. EMC Directive LowVoltage Electrical Products Directive Machines Directive Principal EC Directive 89/336/EEC 92/3/EEC 73/23/EEC 89/392/EEC 7. Immunity egulations in Japan Equipment TV,adio,Audio ITE Office Machine Mi Machine To Builders Industrial Measuring Control Equipment Industrial obot Association JEITA (Japan Electronis and Information Technology) JBMIA (Japan Business Machine and Information System Industries Association) CIAJ (Communication and Information network Association of Japan) AIB (Association of adio Industories and Business) JMTBA (Japan Machine Tool Builders' Association) JEMIMA (Japan Electric Measuring Instruments Manufacturers' Association) JAA (Japan obot Association) The table on the right shows the preparation situation of JIS for EMC. At this moment, the immunity standards by JIS does not have a legal force like Electrical Application and Material Safety Law/VCCI. Classification Terms Information egulation ISO656 (IEV terms 6) JIS JIS C 6 Basic Standard IEC64 2 IEC64 3 IEC64 4 IEC64 5 IEC64 6 IEC64 7 IEC64 8 IEC64 IEC644 IEC647 JIS C 42 JIS C 43 JIS C 44 JIS C 45 JIS C 46 JIS C 47 Under preparation Generic Standard IEC66 IEC662 56
!Note C3E9.pdf 3.3.2 Noise Suppression Principles by DC EMIFILr. Function of DC EMI Suppression Filters DC EMI suppression filters absorb and eliminate high frequency noise which may produce electromagnetic interference in PC board circuits. These filters are used in secondary circuits, and are small in size and light in weight, which further enhances their excellent noise suppression functions. Chip and adhesive type filters can be mounted on PC boards automatically. These filters are effective in the suppression of radiation noise in computers, peripheral equipment, and digital circuit application equipment (including various types of microcomputer application equipment), and function to suppress noise in audio/visual equipment, which uses digital memory chips and DSP. These filters are also effective for improving the noise immunity of equipment used in noisy environments (such as electronic equipment for automobiles). 2. Noise Filter Suppression Principles Generally, noise problems occur when the noise source and electronic equipment sensitive to the influence of noise are located in close proximity to one another. In such situations, as shown in Figure at right, noise is conducted through a conductor, which produces an inductive field around the noise source. To overcome such noise problems, it is preferable to reduce the amount of noise generated by the noise source or improve the noise resistance of adjacent equipment. In order to satisfy equipment performance specifications and eliminate noise effectively at the same time, however, it is customary to reduce the amount of noise generated by the noise source, if it can't be eliminated altogether. [EMI Propagation Mode and Model of Noise Filter Suppression] EMI Source EMI Source e q r q e w r w Equipment or Device Affected by EMI qconduction mode econduction mode adiation mode wadiation mode radiation mode Conduction mode Shield EMI Filter EMI Filter EMI Filter EMI Filter Equipment or Device Affected by EMI Shield 3. Configuration of EMI Suppression Filters (DC) DC EMI suppression filters are used to suppress noise produced by conductors. Noise radiation can be suppressed, if it is eliminated with a filter in advance. Generally, such noise suppression is achieved with DC EMI suppression filters, according to the capacitive and inductive frequency characteristics of the respective conductors in the circuit. Filters of this kind can be roughly divided into those : () employing a capacitor, (2) employing an inductor, (3) employing a capacitor and inductor combination. Continued on the following page. 57
!Note C3E9.pdf 3.3.2 Noise Suppression Principles by DC EMIFILr Continued from the preceding page. 4. Capacitive Noise Suppression When a capacitor is connected (bypass capacitor) to ground from a noisy signal line or power line, the circuit impedance decreases as the frequency increases. Since noise is a high frequency phenomenon, it flows to ground if a capacitor has been connected to ground, thereby making it possible to eliminate noise. (See Fig.) EMI suppression filters employing a capacitor in this way are used to eliminate this type of noise. [Capacitive Noise Suppression] Noise+Signal/DC Power Noise = 2πfc Signal/DC Power f : Frequency c : Capacitance Value 5. High frequency Capacitor Characteristics Used for EMI Suppression Filters Even generalpurpose capacitors can be used for noise suppression. However, since noise has an extremely high frequency range, generalpurpose capacitors may not function as effective bypass capacitors, due to the large residual inductance built into the capacitor. All the capacitors used in MUATA's EMI suppression filters employ a 3 terminal structure or thrutype structure, which functions effectively even at high frequencies, thereby minimizing the influence of residual inductance. Consequently, an effective filter circuit can be formed even at frequencies exceeding GHz. (efer to Fig.) [Equivalent circuit of generalpurpose capacitor and 3 terminal capacitor in the high frequency area and comparison of insertion loss] (a) Construction of capacitor 2terminal capacitor Dielectric Electrode Lead 3terminal capacitor Dielectric Electrode Lead (b) Equivalent circuit of capacitors which is concerning ESL effect. (c) Improvement of Insertion Loss Characteristics Insertion Loss [db] 2 4 6 C=22pf 3terminal capacitor (Builtin Bead) (DSS9HB32E222Q55) 2terminal capacitor 3terminal capacitor (DSN9HB32E222Q55) Ideal Characteristic of capacitor 8 5 5 5 Frequency [MHz] 6. Inductive Noise Suppression When an inductor is inserted in series in a noise producing circuit (See Fig.), its impedance increases with frequency. In this configuration it is possible to attenuate and eliminate noise components (high frequency components). The MUATA EMI suppression filter functions in this way. [Inductive Noise Suppression] Noise+Signal/DC Power Noise = 2πfL Signal/DC Power f : Frequency L : Capacitance Value Continued on the following page. 58
!Note C3E9.pdf 3.3.2 Noise Suppression Principles by DC EMIFILr Continued from the preceding page. 7. Characteristics of Inductors Used in EMI Suppression Filters Generalpurpose inductors also function to suppress noise when configured in series with a noise producing circuit. However, when generalpurpose inductors are used, resonance may result in peripheral circuits, signal wave forms may become distorted, and satisfactory impedance may not be obtained at noise frequencies (due to insufficient high frequency impedance characteristics). The inductors used for MUATA's EMI suppression filters are designed to function nearly as a resistor at noise frequencies, which greatly reduces the possibility of resonance and leaves signal wave forms undistorted. And since sufficient impedance is obtained for frequencies ranging to hundreds of MHz, these specifically designed inductors operate effectively to suppress highfrequency noise. (See Fig.) [Equivalent Circuit] (esistance element becomes dominant at high frequency.) [Example of impedance frequency characteristics of inductor type EMIFILr] Impedance [Ω] 6 4 2 8 6 4 2 BL2N2.5 (f) 2 5 2 5 2 5 Frequency [MHz] 8. CapacitiveInductive EMI Suppression Filters If capacitive and inductive suppression characteristics are combined, it is possible to configure a much higher performance filter. In signal circuit applications where this combination is applied, noise suppression effects which have little influence on the signal wave form become possible. This type of filter is also effective in the suppression of highspeed signal circuit noise. When used in DC power circuits, capacitiveinductive filters prevent resonance from occurring in peripheral circuits, thus making it possible to achieve significant noise suppression under normal service conditions. 9. Other EMI Suppression Filters In addition to the capacitiveinductive filter, MUATA also has an EMI suppression filter (EMIGUADr) combining a capacitor with a varistor, useful for surge absorption; and a common mode choke coil effective, for common mode noise suppression. MUATA also has a range of builtin filter connectors which greatly reduce filter mounting space requirements. Continued on the following page. 59
!Note C3E9.pdf 3.3.2 Noise Suppression Principles by DC EMIFILr Continued from the preceding page.. Expressing EMI Suppression Filter Effects EMI Suppression Filter effects are expressed in terms of the insertion loss measured in the circuit, normally specified in MILSTD 22A. As shown in the 5Ω impedance circuit in the Figure at right, insertion loss is represented by the logarithmic ratio of the circuit output voltage with and without a filter in the circuit, which is multiplied by 2 and expressed in db. Therefore, an insertion loss of 2dB indicates an output voltage ratio (B/C) of /, and an insertion loss of 4dB indicates an output voltage ratio (B/C) of /. [Measuring Circuit of Insertion Loss] Measuring Circuit of Insertion Loss (a) (b) A(V) A(V) 5Ω 5Ω EMI Suppression Filter B(V) C(V) 5Ω 5Ω Insertion Loss = 2 log B (db) C 6
!Note Please read rating and!caution (for storage, operating, rating, soldering, mounting and handling) in this PDF catalog to prevent smoking and/or burning, etc. C3E9.pdf 3.3.2 This catalog has only typical specifications. Therefore, you are requested to approve our product specifications or to transact the approval sheet for product specificaions before ordering. Murata EMI Filter Selection Simulator Ver.2.5. ecommended Chip Ferrite Beads Search procedure has been added Select circuit. (Select a new simulation circuit from File menu.) 2 Enter "Input Signal". 3 Set Driver IC. Simulation results with various charts are quickly displayed on your PC. esults can be displayed in standard format or user defined scaling. Simulates various types of circuit such as Differential ModeTransmission, ceramic capacitor, EMIFILr three terminal capacitor AND chip ferrite beads. Provides a simulation function that select best suited Chip Ferrite Beads. Select circuit. Select a new simulation circuit from File menu. 2 4 7 6 3 5 4 Select filter. (EMI filters or/and chip capacitor from the pulldown list.) 4 Filters can be selected from "frequencyimpedance characteristics" charts. 8 5 Set Transmission Line. 9 Simulation results are shown in the window. Two ways of setting the driver/receiver IC parameter The logic IC of TTL and CMOS can be selected from pulldown list or the LC values can also be created. Impedance automatically calculated. Impedance characteristics of transmission line are automatically calculated. 6 Set eceiver IC. 7 Click measuring point. (Only for chip ferrite bead) Find ecommended Ferrite Beads NEW 8 Click "Start Simulation" button. The software will recommend the most appropriate ferrite beads solution based on specified search condition. 9 Simulation results are displayed. The recommended parts will be displayed along with electrical characteristics, the voltage waveform and spectrum chart. EMIFILr is the trademark of Murata Manufacturing Co., Ltd. This simulator can be downloaded from Murata web site. http://www.murata.com/emi/ 6