Hall IC eries / Hall IC(Latch type) Unipolar Detection Hall ICs BU522GUL, BU523GUL, BU5212HFV, BU5213HFV Description The unipolar Detection Hall IC detects only either the pole or pole. The output turns O (active Low) upon detection. It is most suitable for strictly unipole detection and when lower power consumption is desired. Features 1) unipolar detection 2) Micropower operation (small current using intermittent operation method) 3) Ultra-compact CP4 package (BU522GUL,BU523GUL) 4) mall outline package (BU5212HFV,BU5213HFV) 5) Line up of supply voltage For 1.8V Power supply voltage(bu5212hfv,bu5213hfv) For 3.V Power supply voltage (BU522GUL,BU523GUL) 6) High ED resistance 8kV(HBM) Applications Mobile phones, notebook computers, digital video camera, digital still camera, etc. Product Lineup Product name upply voltage (V) Operate point (mt) Hysteresis (mt) Period (ms) upply current (AVG. ) (μa) Output type Package BU522GUL 2.4~3.3 3.7.8 5 6.5 CMO VCP5L1 BU523GUL 2.4~3.3-3.7.8 5 6.5 CMO VCP5L1 BU5212HFV 1.65~3.3 3..9 5 3.5 CMO HVOF5 BU5213HFV 1.65~3.3-3..9 5 3.5 CMO HVOF5 Plus is expressed on the -pole; minus on the -pole June 28 REV. G
Absolute Maximum Ratings BU522GUL,BU523GUL (Ta=25 ) BU5212HFV,BU5213HFV (Ta=25 ) PARAMETER YMBOL LIMIT UIT PARAMETER YMBOL LIMIT UIT Power upply Voltage V DD -.1~+4.5 1 V Power upply Voltage V DD -.1~+4.5 3 V Output Current I ±1 ma Output Current I ±.5 ma Power Dissipation Pd 42 2 mw Power Dissipation Pd 536 4 mw Operating Temperature Range T opr -4~+85 Operating Temperature Range T opr -4~+85 torage Temperature Range T stg -4~+125 torage Temperature Range T stg -4~+125 1. ot to exceed Pd 2. Reduced by 4.2mW for each increase in Ta of 1 over 25 (mounted on 5mm 58mm Glass-epoxy PCB) 3. ot to exceed Pd 4. Reduced by 5.36mW for each increase in Ta of 1 over 25 (mounted on 7mm 7mm 1.6mm Glass-epoxy PCB) Magnetic, Electrical Characteristics BU522GUL (Unless otherwise specified, V DD =3.V, Ta=25 ) PARAMETER YMBOL LIMIT MI TYP MAX UIT CODITIO Power upply Voltage V DD 2.4 3. 3.3 V Operate Point B op - 3.7 5.5 mt Release Point B rp.8 2.9 - mt Hysteresis B hys -.8 - mt Period T P - 5 1 ms Output High Voltage V OH V DD -.4 - - V B<B rp 5 I =-1.mA Output Low Voltage V OL - -.4 V B op <B 5 I =+1.mA I DD(AVG) - 6.5 9 μa Average During tartup Time During tandby Time I DD(E) - 4.7 - ma During tartup Time Value I DD(DI) - 3.8 - μa During tandby Time Value 5. B = Magnetic flux density 1mT=1Gauss Positive ( + ) polarity flux is defined as the magnetic flux from south pole which is direct toward to the branded face of the sensor. After applying power supply, it takes one cycle of period (T P ) to become definite output. Radiation hardiness is not designed. 2/14
BU523GUL (Unless otherwise specified, V DD =3.V, Ta=25 ) PARAMETER YMBOL LIMIT MI TYP MAX UIT CODITIO Power upply Voltage V DD 2.4 3. 3.3 V Operate Point B op -5.5-3.7 - mt Release Point B rp - -2.9 -.8 mt Hysteresis B hys -.8 - mt Period T P - 5 1 ms Output High Voltage V OH V DD -.4 - - V B rp <B 6 I =-1.mA Output Low Voltage V OL - -.4 V B<B op 6 I =+1.mA I DD(AVG) - 6.5 9 μa Average During tartup Time During tandby Time I DD(E) - 4.7 - ma During tartup Time Value I DD(DI) - 3.8 - μa During tandby Time Value BU5212HFV (Unless otherwise specified, V DD =1.8V, Ta=25 ) PARAMETER YMBOL LIMIT MI TYP MAX UIT CODITIO Power upply Voltage V DD 1.65 1.8 3.3 V Operate Point B op - 3. 5. mt Release Point B rp.6 2.1 - mt Hysteresis B hys -.9 - mt Period T P - 5 1 ms Output High Voltage V OH V DD -.2 - - V B<B rp 6 I =-.5mA Output Low Voltage V OL - -.2 V B op <B 6 I =+.5mA 1 I DD1(AVG) - 3.5 5.5 μa V DD =1.8V, Average During tartup Time 1 During tandby Time 1 I DD1(E) - 2.8 - ma I DD1(DI) - 1.8 - μa V DD =1.8V, During tartup Time Value V DD =1.8V, During tandby Time Value 2 I DD2(AVG) - 6.5 9 μa V DD =2.7V, Average During tartup Time 2 During tandby Time 2 I DD2(E) - 4.5 - ma I DD2(DI) - - μa V DD =2.7V, During tartup Time Value V DD =2.7V, During tandby Time Value 6. B = Magnetic flux density 1mT=1Gauss Positive ( + ) polarity flux is defined as the magnetic flux from south pole which is direct toward to the branded face of the sensor. After applying power supply, it takes one cycle of period (T P ) to become definite output. Radiation hardiness is not designed. 3/14
BU5213HFV (Unless otherwise specified, V DD =1.8V, Ta=25 ) PARAMETER YMBOL LIMIT MI TYP MAX UIT CODITIO Power upply Voltage V DD 1.65 1.8 3.3 V Operate Point B op -5. -3. - mt Release Point B rp - -2.1 -.6 mt Hysteresis B hys -.9 - mt Period T P - 5 1 ms Output High Voltage V OH V DD -.2 - - V B rp <B 7 I =-.5mA Output Low Voltage V OL - -.2 V B<B op 7 I =+.5mA 1 I DD1(AVG) - 3.5 5.5 μa V DD =1.8V, Average During tartup Time 1 During tandby Time 1 I DD1(E) - 2.8 - ma I DD1(DI) - 1.8 - μa V DD =1.8V, During tartup Time Value V DD =1.8V, During tandby Time Value 2 I DD2(AVG) - 6.5 9 μa V DD =2.7V, Average During tartup Time 2 During tandby Time 2 I DD2(E) - 4.5 - ma I DD2(DI) - - μa V DD =2.7V, During tartup Time Value V DD =2.7V, During tandby Time Value 7. B = Magnetic flux density 1mT=1Gauss Positive ( + ) polarity flux is defined as the magnetic flux from south pole which is direct toward to the branded face of the sensor. After applying power supply, it takes one cycle of period (T P ) to become definite output. Radiation hardiness is not designed. 4/14
Figure of mesurement circuit B op /B rp T p 2Ω 1μF GD V Oscilloscope GD Bop and Brp are measured with applying the magnetic field The period is monitored by Oscilloscope. from the outside. Fig.1 B op,b rp mesurement circuit Fig.2 T p mesurement circuit V OH Product ame I BU522GUL, BU523GUL 1.mA 1μF BU5212HFV, BU5213HFV.5mA GD V I Fig.3 V OH mesurement circuit V OL Product ame I BU522GUL, BU523GUL 1.mA 1μF BU5212HFV, BU5213HFV.5mA GD V I Fig.4 V OL mesurement circuit I DD A 22μF GD Fig.5 I DD mesurement circuit 5/14
Technical (Reference) Data BU522GUL (V DD =2.4~3.3V type) MAGETIC FLUX DEITY [mt] - - - V DD =3.V Bop Brp - Fig.6 Bop,Brp MAGETIC FLUX DEITY [mt] Ta = 25 C Bop Brp - - - - 2.4 2.8 3.2 3.6 Fig.7 Bop,Brp upply voltage 1 9 8 7 6 5 4 3 2 1 V DD =3.V Fig.8 T P 1 9 8 Ta = 25 C 7 6 5 4 3 2 1 2.4 2.8 3.2 3.6 Fig.9 T P upply voltage AVERAGE UPPLY CURRET [µa] 2 1 1 1 1 1 V DD =3.V Fig.1 I DD AVERAGE UPPLY CURRET [µa] 2 1 1 Ta = 25 C 1 1 1 2.4 2.8 3.2 3.6 Fig.11 I DD upply voltage BU523GUL (V DD =2.4~3.3V type) MAGETIC FLUX DEITY [mt] - - - V DD =3.V Brp Bop - Fig.12 Bop,Brp MAGETIC FLUX DEITY [mt] Ta = 25 C - Brp - - Bop - 2.4 2.8 3.2 3.6 Fig.13 Bop,Brp upply voltage 1 9 8 7 6 5 4 3 2 1 V DD =3.V Fig.14 T P 1 9 8 7 6 5 4 3 2 1 Ta = 25 C 2.4 2.8 3.2 3.6 Fig.15 T P upply voltage AVERAGE UPPLY CURRET [µa] 2 1 V 1 DD =3.V 1 1 1 Fig.16 I DD AVERAGE UPPLY CURRET [µa] 2 1 1 Ta = 25 C 1 1 1 2.4 2.8 3.2 3.6 Fig.17 I DD upply voltage 6/14
BU5212HFV (V DD =1.65~3.3V type) MAGETIC FLUX DEITY [mt] V DD =1.8V Bop Brp - - - - Fig.18 Bop,Brp MAGETIC FLUX DEITY [mt] - - - - Ta = 25 C Bop Brp 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.19 Bop,Brp upply voltage 1 9 8 7 6 5 4 3 2 1 V DD =1.8V Fig.2 T P 1 9 8 7 6 5 4 3 2 1 Ta = 25 C 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.21 T P upply voltage BU5213HFV (V DD =1.65~3.3V type) MAGETIC FLUX DEITY [mt] V DD =1.8V Brp - - Bop - - Fig.24 Bop,Brp AVERAGE UPPLY CURRET [µa] MAGETIC FLUX DEITY [mt] 2 1 1 1 1 1 V DD =1.8V - - - - Fig.22 I DD Ta = 25 C Brp Bop 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.25 Bop,Brp upply voltage AVERAGE UPPLY CURRET [µa] 2 1 1 1 1 1 Ta = 25 C 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.23 I DD upply voltage 1 9 V DD =1.8V 8 7 6 5 4 3 2 1 Fig.26 T P 1 9 8 Ta = 25 C 7 6 5 4 3 2 1 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.27 T P upply voltage AVERAGE UPPLY CURRET [µa] 2 1 1 1 1 1 V DD =1.8V Fig.28 I DD AVERAGE UPPLY CURRET [µa] 2 1 1 Ta = 25 C 1 1 1 1.4 1.8 2.2 2.6 3. 3.4 3.8 Fig.29 I DD upply voltage 7/14
Block Diagram BU522GUL, BU523GUL A1.1μF Adjust the bypass capacitor HALL ELEMET DYAMIC OFFET CACELLATIO TIMIG LOGIC AMPLE & HOLD LATCH B1 value as necessary, according to voltage noise conditions, etc. The CMO output terminals enable direct connection to the PC, with no external pull-up resistor required. A2 GD Fig.3 PI o. PI AME FUCTIO COMMET A1 A2 A2 A1 A1 POWER UPPLY A2 GD GROUD B1 PUT B2.C. OPE or hort to GD. B1 B2 urface B2 B1 Reverse BU5212HFV, BU5213HFV HALL ELEMET DYAMIC OFFET CACELLATIO TIMIG LOGIC AMPLE & HOLD 4 LATCH 5.1μF Adjust the bypass capacitor value as necessary, according to voltage noise conditions, etc. The CMO output terminals enable direct connection to the PC, with no external pull-up resistor required. 2 GD Fig.31 PI o. PI AME FUCTIO COMMET 1.C. OPE or hort to GD. 5 4 4 5 2 GD GROUD 3.C. OPE or hort to GD. 4 POWER UPPLY 5 PUT 1 2 3 urface 3 2 1 Reverse 8/14
Description of Operations (Micropower Operation) I DD Period tartup time tandby The unipolar detection Hall IC adopts an intermittent operation method to save energy. At startup, the Hall elements, amp, comparator and other detection circuits power O and magnetic detection begins. During standby, the detection circuits power OFF, thereby reducing current consumption. The detection results are held while standby is active, and then output. t (Offset Cancelation) Fig.32 Reference period: 5ms (MAX1ms) Reference startup time: 24μs V DD B GD Fig.33 I + - Hall Voltage The Hall elements form an equivalent Wheatstone (resistor) bridge circuit. Offset voltage may be generated by a differential in this bridge resistance, or can arise from changes in resistance due to package or bonding stress. A dynamic offset cancellation circuit is employed to cancel this offset voltage. When Hall elements are connected as shown in Fig. 33 and a magnetic field is applied perpendicular to the Hall elements, voltage is generated at the mid-point terminal of the bridge. This is known as Hall voltage. Dynamic cancellation switches the wiring (shown in the figure) to redirect the current flow to a 9 angle from its original path, and thereby cancels the Hall voltage. The magnetic signal (only) is maintained in the sample/hold circuit during the offset cancellation process and then released. (Magnetic Field Detection Mechanism) Flux Flux Fig.34 The Hall IC cannot detect magnetic fields that run horizontal to the package top layer. Be certain to configure the Hall IC so that the magnetic field is perpendicular to the top layer. 9/14
BU522GUL,BU5212HFV -Pole [V] High Flux High Flux High Low B -Pole Magnetic flux density [mt] Brp -Pole Bop Fig.35 -Pole Detection BU522GUL,BU5212HFV detects and outputs for the -pole only. ince it is unipolar, it does not recognize the -pole. BU523GUL,BU5213HFV -Pole [V] High Flux High Flux High Low Bop -Pole Brp Magnetic flux density [mt] -Pole B Fig.36 -Pole Detection BU523GUL,BU5213HFV detects and outputs for the -pole only. ince it is unipolar, it does not recognize the -pole. The unipolar detection Hall IC detects magnetic fields running perpendicular to the top surface of the package. There is an inverse relationship between magnetic flux density and the distance separating the magnet and the Hall IC: when distance increases magnetic density falls. When it drops below the operate point (Bop), output goes HIGH. When the magnet gets closer to the IC and magnetic density rises, to the operate point, the output switches LOW. In LOW output mode, the distance from the magnet to the IC increases again until the magnetic density falls to a point just below Bop, and output returns HIGH. (This point, where magnetic flux density restores HIGH output, is known as the release point, Brp.) This detection and adjustment mechanism is designed to prevent noise, oscillation and other erratic system operation. 1/14
Intermittent Operation at Power O Power O upply current (Intermittentaction) tartup time tandby time tandby time tartup time (o magnetic field present) (Magnetic field present) Indefinite Indefinite High Low Fig.37 The unipolar detection Hall IC adopts an intermittent operation method in detecting the magnetic field during startup, as shown in Fig. 37. It outputs to the appropriate terminal based on the detection result and maintains the output condition during the standby period. The time from power O until the end of the initial startup period is an indefinite interval, but it cannot exceed the maximum period, 1ms. To accommodate the system design, the Hall IC output read should be programmed within 1ms of power O, but after the time allowed for the period ambient temperature and supply voltage. Magnet election Of the two representative varieties of permanent magnet, neodymium generally offers greater magnetic power per volume than ferrite, thereby enabling the highest degree of miniaturization, Thus, neodymium is best suited for small equipment applications. Fig. 38 shows the relation between the size (volume) of a neodymium magnet and magnetic flux density. The graph plots the correlation between the distance (L) from three versions of a 4mm X 4mm cross-section neodymium magnet (1mm, 2mm, and 3mm thick) and magnetic flux density. Fig. 39 shows Hall IC detection distance a good guide for determining the proper size and detection distance of the magnet. Based on the BU5212HFV,BU5213HFV operating point max 5. mt, the minimum detection distance for the 1mm, 2mm and 3mm magnets would be 7.6mm, 9.22mm, and 1.4mm, respectively. To increase the magnet s detection distance, either increase its thickness or sectional area. 1 Magnetic flux density[mt] 9 8 7 6 5 4 3 2 t=1mm t=3mm t=2mm 1 7.6mm 9.2mm 1.4mm 2 4 6 8 1 12 14 16 18 2 Distance between magnet and Hall IC [mm] Y Magnet size X t X=Y=4mm t=1mm,2mm,3mm Fig.39 Magnet Dimensions and Flux Density Measuring Point Fig.38 Magnet t L: Variable Flux density measuring point Magnet material: EOMAX-44H (material) Maker: EOMAX CO.,LTD. 11/14
Position of the Hall Effect IC(Reference) VCP5L1.55 HVOF5.6.55.8.35.2 (UIT:mm) Footprint dimensions (Optimize footprint dimensions to the board design and soldering condition) VCP5L1 HVOF5 (UIT:mm) Terminal Equivalent Circuit Diagram Because they are configured for CMO (inverter) output, the output pins require no external resistance and allow direct connection to the PC. This, in turn, enables reduction of the current that would otherwise flow to the external resistor during magnetic field detection, and supports overall low current (micropower) operation. Fig.4 GD 12/14
Operation otes 1) Absolute maximum ratings Exceeding the absolute maximum ratings for supply voltage, operating conditions, etc. may result in damage to or destruction of the IC. Because the source (short mode or open mode) cannot be identified if the device is damaged in this way, it is important to take physical safety measures such as fusing when implementing any special mode that operates in excess of absolute rating limits. 2) GD voltage Make sure that the GD terminal potential is maintained at the minimum in any operating state, and is always kept lower than the potential of all other pins. 3) Thermal design Use a thermal design that allows for sufficient margin in light of the power dissipation (Pd) in actual operating conditions. 4) Pin shorts and mounting errors Use caution when positioning the IC for mounting on printed circuit boards. Mounting errors, such as improper positioning or orientation, may damage or destroy the device. The IC may also be damaged or destroyed if output pins are shorted together, or if shorts occur between the output pin and supply pin or GD. 5) Positioning components in proximity to the Hall IC and magnet Positioning magnetic components in close proximity to the Hall IC or magnet may alter the magnetic field, and therefore the magnetic detection operation. Thus, placing magnetic components near the Hall IC and magnet should be avoided in the design if possible. However, where there is no alternative to employing such a design, be sure to thoroughly test and evaluate performance with the magnetic component(s) in place to verify normal operation before implementing the design. 6) Operation in strong electromagnetic fields Exercise extreme caution about using the device in the presence of a strong electromagnetic field, as such use may cause the IC to malfunction. 7) Common impedance Make sure that the power supply and GD wiring limits common impedance to the extent possible by, for example, employing short, thick supply and ground lines. Also, take measures to minimize ripple such as using an inductor or capacitor. 8) GD wiring pattern When both a small-signal GD and high-current GD are provided, single-point grounding at the reference point of the set PCB is recommended, in order to separate the small-signal and high-current patterns, and to ensure that voltage changes due to the wiring resistance and high current do not cause any voltage fluctuation in the small-signal GD. In the same way, care must also be taken to avoid wiring pattern fluctuations in the GD wiring pattern of external components. 9) Exposure to strong light Exposure to halogen lamps, UV and other strong light sources may cause the IC to malfunction. If the IC is subject to such exposure, provide a shield or take other measures to protect it from the light. In testing, exposure to white LED and fluorescent light sources was shown to have no significant effect on the IC. 1) Power source design ince the IC performs intermittent operation, it has peak current when it s O. Please taking that into account and under examine adequate evaluations when designing the power source. 13/14
Product Designations (electing a model name when ordering) B U 5 2 2 G U L E 2 ROHM model VCP5L1 <Dimensions> 1PI MARK Part number 1.1.1.1 5 1.1.1.55MAX Package type VCP5L1 HVOF5 : GUL : HFV TR, E2 = Reel-wound embossed taping VCP5L1 HVOF5 < Tape/Reel Info > Tape Embossed carrier tape Quantity 3pcs Direction of feed : E2 : TR E2 (Correct direction: With reel in the left hand, the 1pin of the product should be at the upper left. Pull tape out with the right hand) 8 4-.25 5 5 A B A.3.1 1234 1234 1234 1234 1234 1234 B A 1 2.3.1.5.5 B (Unit: mm) Reel Direction of feed 1pin Orders are available in complete units only. HVOF5 <Dimensions> < Tape/Reel Info > Tape Embossed carrier tape Quantity 3pcs Direction of feed TR (Correct direction: With reel in the left hand, the 1pin of the product should be at the upper left. Pull tape out with the right hand) (Unit: mm) Reel 1pin Feed direction Orders are available in complete units only. 14/14 Catalog o.8t157a '8.6 ROHM 1 Z
Appendix otes o technical content pages of this document may be reproduced in any form or transmitted by any means without prior permission of ROHM CO.,LTD. The contents described herein are subject to change without notice. The specifications for the product described in this document are for reference only. Upon actual use, therefore, please request that specifications to be separately delivered. Application circuit diagrams and circuit constants contained herein are shown as examples of standard use and operation. Please pay careful attention to the peripheral conditions when designing circuits and deciding upon circuit constants in the set. Any data, including, but not limited to application circuit diagrams information, described herein are intended only as illustrations of such devices and not as the specifications for such devices. ROHM CO.,LTD. disclaims any warranty that any use of such devices shall be free from infringement of any third party's intellectual property rights or other proprietary rights, and further, assumes no liability of whatsoever nature in the event of any such infringement, or arising from or connected with or related to the use of such devices. Upon the sale of any such devices, other than for buyer's right to use such devices itself, resell or otherwise dispose of the same, no express or implied right or license to practice or commercially exploit any intellectual property rights or other proprietary rights owned or controlled by ROHM CO., LTD. is granted to any such buyer. Products listed in this document are no antiradiation design. The products listed in this document are designed to be used with ordinary electronic equipment or devices (such as audio visual equipment, office-automation equipment, communications devices, electrical appliances and electronic toys). hould you intend to use these products with equipment or devices which require an extremely high level of reliability and the malfunction of which would directly endanger human life (such as medical instruments, transportation equipment, aerospace machinery, nuclear-reactor controllers, fuel controllers and other safety devices), please be sure to consult with our sales representative in advance. It is our top priority to supply products with the utmost quality and reliability. However, there is always a chance of failure due to unexpected factors. Therefore, please take into account the derating characteristics and allow for sufficient safety features, such as extra margin, anti-flammability, and fail-safe measures when designing in order to prevent possible accidents that may result in bodily harm or fire caused by component failure. ROHM cannot be held responsible for any damages arising from the use of the products under conditions out of the range of the specifications or due to non-compliance with the OTE specified in this catalog. Thank you for your accessing to ROHM product informations. More detail product informations and catalogs are available, please contact your nearest sales office. ROHM Customer upport ystem THE AMERICA / EUROPE / AIA / JAPA www.rohm.com Contact us : webmaster@ rohm.co.jp Copyright 28 ROHM CO.,LTD. 21 aiin Mizosaki-cho, Ukyo-ku, Kyoto 615-8585, Japan TEL : +81-75-311-2121 FAX : +81-75-315-172 Appendix1-Rev