LOW VOLTAGE VIDEO AMPLIFIER WITH LPF

LOW VOLTAGE VIDEO AMPLIFIER WITH LPF GENRERAL DESCRIPTION The NJM2574 is a Low Voltage Video Amplifier contained LPF circuit, driver and internal CLAMP/BIAS, LPF/through to connect TV monitor directly. The input signal is composite signal (Vpp). The mute circuit with power save function is suitable for low power design. The NJM2574 is suitable for down sizing of Digital Steel Camera, and DVC for small package. PACKAGE OUTLINE NJM2574RB1 ( MSOP8 (TVSP8) ) FEATURES Operating Voltage 2.8 to 5.5V Input Composite Signal Vpp 12dB Amplifier Driver Internal CLAMP/BIAS Internal LPF/through Operating Current 9.0mA typ. at Vcc=V Operating Current in Battery Saving 70µA typ. at Vcc=V Bipolar Technology Package Outline MSOP8 (TVSP8)* *MEET JEDEC MO-187-DA / THIN TYPE BLOCK DIAGRAM LPF/Through 1 5 Vin 6 LPF 12dB Driver 4 Vout CLAMP/BIAS 8 3 Vsag CLAMP BIAS 2 GND 7 Power Save Ver.13-1-

ABSOLUTE MAXIMUM RATINGS (Ta=25 C) PARAMETER SYMBOL RATINGS UNIT Supply Voltage 7.0 V Power Dissipation P D 320 mw Operating Temperature Range Topr -40 to 85 C Storage Temperature Range Tstg -40 to 125 C ELECTRICAL CHARACTERISTICS ( =V,RL=150Ω,Ta=25 C) PARAMETER SYMBOL TEST CONDITION MIN. TYP. MAX. UNIT Operating Voltage Vopr 2.8 5.5 V Operating Current I CC No Signal - 9.0 1 ma Operating Current at Power Save Isave Power Save Mode - 70 90 µa Maximum Output Voltage Swing f=1khz,thd=1%,clamp MODE Vomv 2.2 2.7 - LPF MODE Vom f=1khz,thd=1%, 1.4 - RGB BIAS MODE, through MODE Vp-p Voltage Gain Gv Vin=100kHz,Vp-p, Input Sine Signal 1 12.4 12.8 db Frequency Characteristic (Through MODE) Gf Vin=20MHz/100kHz,Vp-p -6.0 - - db Low Pass Filter Characteristic Gfy4.5M Vin=4.5MHz/100kHz,Vp-p -0.95-0.45 5 Gfy8M Vin=8MHz/100kHz,Vp-p - - - Gfy23.5M Vin=23.5MHz/100kHz,Vp-p - -23-17 Differential Gain DG Vin=Vp-p, Input 10step Video Signal - - % Differential Phase DP Vin=Vp-p, Input 10step Video Signal - - deg S/N SNv Vin=Vp-p, 100% White Video Signal, R L = - 60 - db Band Width 100kHz to 6MHz 2nd. Distortion Hv Vin=Vp-p, 3.58MHz, Sine Video Signal, R L =, - -60 - db Change Voltage High Level VthH 1.8 - Change Voltage Low Level VthL 0-0.3 V db CONTROL TERMINAL PARAMETER STATUS NOTE H Power Save : OFF Power Save(7pin) L Power Save : ON (Mute) OPEN Power Save : ON (Mute) H LPF MODE LPF/Through (1pin) L Through MODE OPEN Through MODE H CLAMP MODE CLAMP/BIAS (8pin) L BIAS MODE OPEN BIAS MODE - 2 -

TEST CIRCUIT Power save Vin CLAMP/BIAS 8 7 6 5 10µF NJM2574 1 2 3 4 GND 22µF 100µF Vsag LPF/Through Vout -3-

APPLICATION CIRCUIT (1) Standard circuit Vin (2) SAG correction unused circuit Vin Power save Power save 10µF CLAMP/BIAS 8 7 6 5 NJM2574 1 2 3 4 33µF C1 33µF GND (3) Two-line driving circuit CLAMP/BIAS LPF/Through Power save Vin Vout 8 7 6 5 10µF CLAMP/BIAS 8 7 6 5 NJM2574 1 2 3 4 LPF/Through GND Vout 470µF 10µF NJM2574 1 2 3 4 GND 470µF LPF/Through Vout2 Vout1 (1) Standard circuit This circuit is for a portable equipment of small mounting space. The SAG correction reduces output coupling capacitor values. However, this circuit may cause to SAG deterioration, and lose synchronization by luminance fluctuation. Adjust the C1 value, checking the waveform containing a lot of low frequency components like a bounce waveform (Worst condition waveform of SAG). Change the capacitor of C1 into a large value to improve SAG. (2) SAG correction unused circuit We recommend this circuit when there is no space limitation. Connect the coupling capacitor after connecting the Vout pin and Vsag pin. The recommended value is 470µF or more. (3) Two-line driving circuit This circuit drives two-line of 150Ω. However, it may cause to lose synchronization by an input signal of large APL change (100% white signals more than 1Vp-p). Confirm the large APL change waveform (100% white signals more than 1Vp-p) and evaluate sufficiently. - 4 -

APPLICATION (IC characteristic is not guaranteed) When you use a power save terminal more than by V, please put resistance of about 20kΩ into a power save terminal. Resistance is unnecessary in the following condition. 1. The power save terminal voltage (VthH) is less than V. 2. When you select "BIAS" at the power-supply voltage of 5V. Example) PS(VthH) V PS(VthH) < V Power Save r V PS (VthH) VthH V r 20kΩ Power Save V PS (VthH) VthH < V -5-

TERMINAL DESCRIPTION No SYMBOL EQUIVALENT CIRCUIT 1 LPF/Through 32KΩ 48KΩ 2 GND 3 Vsag 750Ω 25.3KΩ 4 Vout 750Ω 25.3KΩ 5-6 -

TERMINAL DESCRIPTION No SYMBOL EQUIVALENT CIRCUIT 6 Vin 270Ω 270Ω V 20KΩ 270Ω 7 PowerSave 16k 32k 16k 48k GND 8 CLAMP/BIAS 32KΩ 48KΩ -7-

TYPICAL CHARACTERISTICS Voltage Gain vs. Freqency 20 10 Voltage Gain Gv(dB) 0-10 -20-30 ClampLPF BiasThrough -40 100 10 3 1 10 6 10 10 6 Frequency(Hz) 20 Voltage Gain vs. Freqency (ClampLPF Input) 20 Voltage Gain vs. Freqency (BiasThrough Input) 10 10 Voltage Gain Gv(dB) 0-10 -20 Voltage Gain Gv(dB) 0-10 -20-30 -30-40 100 10 3 1 10 6 10 10 6-40 100 10 3 1 10 6 10 10 6 Frequency(Hz) Frequency(Hz) Operationg Current Icc(mA) Operating Condition: Current CLAMPLPF vs. Supply INPUT Voltage 1 1 8.0 6.0 Operating Current at Standby State Isave(uA) 12 10 8 6 4 2 Operating Current at Standby State vs. Supply Voltage - 8 -

TYPICAL CHARACTERISTICS Maximum Output Voltage Swing vs. Supply Voltage (ClampLPF Type Input) Total Harmonic Distortion=1%, 1kHz 6.0 Maximum Output Voltage Swing Vomv(Vpp) 5.0 Vin Vomv Maximum Output Voltage Swing vs. Supply Voltage (BiasThrough Type Input) Total Harmonic Distortion=1%, 1kHz 6.0 Maximum Output Voltage Swing VomRGB(Vpp) 5.0 Vin VomRGB 1 Voltage Gain vs. Supply Voltage Vpp, 100kHz sinewave signal input Gain Frequency Characteristics vs. Supply Voltage (BiasThrough Type Input) Vpp, 20MHz/100kHz Voltage Gain Gv(dB) 13.5 1 12.5 1 1 1 Gain Frequency Characteristics Gf(dB) - - -6.0-8.0-1 Low Pass Filter Characteristic 1 vs. Supply Voltage (ClampLPF Type Input) Vpp, 4.5MHz/100kHz Low Pass Filter Characteristic 2 vs. Supply Voltage (ClampLPF Type Input) Vpp, 8MHz/100kHz LPF Characteristic 1 Gfy4.5M(dB) - - - LPF Characteristic 2 Gfy8M(dB) - - -6.0-8.0 - -1-9-

TYPICAL CHARACTERISTICS Low Pass Filter Characteristic 3 vs. Supply Voltage (ClampLPF Type Input) Vpp, 23.5MHz/100kHz -16.0-18.0-2 -2-2 -26.0-28.0-3 -3 LPF Characteristic 3 Gfy23.5M(dB) Differential Gain DG(%) Differential Gain vs. Supply Voltage Vpp, 10step video signal input 3.5 2.5 Differential Phase vs. Supply Voltage Vpp, 10step video signal input Signal to Noise Ratio vs. Supply Voltage Vpp, 100% white video signal input, 100kHz-6MHz 10 Differential Phase DP(deg) 3.5 2.5 Signal to Noise Ratio SNv(dB) 9 8 7 6 5 4 Second Harmonic Distortion Hv(dB) Second Harmonic Distortion vs. Supply Voltage Vpp, 3.58MHz sinewave signal input -2-3 -4-5 -6-7 -8-9 -10 Switching Voltage Vth(V) Switching Voltage vs. Supply Voltage VthH VthL - 10 -

TYPICAL CHARACTERISTICS PowerSave Switching Voltage vs. Supply Voltage Operating Current vs. Temperature PowerSave Switching Voltage VthP(V) VthPH VthPL Operationg Current Icc(mA) 1 1 9.0 8.0 7.0 6.0 5.0 Operating Current at Standby State Isave(uA) 10 8 6 4 2 Operating Current at Standby State vs. Temperature Maximum Output Voltage Swing vs. Temperature (ClampLPF Type Input) 6.0 Total Harmonic Distortion=1%, 1kHz 5.0 Maximum Output Voltage Swing Vomv(Vpp) Maximum Output Voltage Swing vs. Temperature (BiasThrough Type Input) 6.0 Total Harmonic Distortion=1%, 1kHz 5.0 Maximum Output Voltage Swing VomRGB(Vpp) Gain Frequency Characteristics Gf(dB) Gain Frequency Characteristics vs. Temperature (BiasThrough Type Input) Vpp, 20MHz/100kHz - - -6.0-8.0-1 -11-

TYPICAL CHARACTERISTICS Low Pass Filter Characteristic 1 vs. Temperature (ClampLPF Type Input) Vpp, 4.5MHz/100kHz Low Pass Filter Characteristic 2 vs. Temperature (ClampLPF Type Input) Vpp, 8MHz/100kHz LPF Characteristic 1 Gfy4.5M(dB) - - - LPF Characteristic 2 Gfy8M(dB) - - -6.0-8.0 - -1 LPF Characteristic 3 Gfy23.5M(dB) Low Pass Filter Characteristic 3 vs. Temperature (ClampLPF Type Input) Vpp, 23.5MHz/100kHz -16.0-18.0-2 -2-2 -26.0-28.0-3 Differential Gain DG(%) 3.5 2.5 Differential Gain vs. Temperature Vpp, 10step video signal input -3 Differential Phase vs. Temperature Vpp, 10step video signal input Signal to Noise Ratio vs. Temperature Vpp, 100% white video signal input, 100kHz-6MHz 10 Differential Phase DP(deg) 3.5 2.5 Signal to Noise Ratio SNv(dB) 9 8 7 6 5 4-12 -

TYPICAL CHARACTERISTICS Second Harmonic Distortion Hv(dB) Second Harmonic Distortion vs. Temperature Vpp, 3.58MHz sinewave signal input -2-3 -4-5 -6-7 -8-9 Switching Voltage Vth(V) Switching Voltage vs. Temperature VthH VthL -10 PowerSave Switching Voltage vs. Temperature PowerSave Switching Voltage VthP(V) VthPH VthPL [CAUTION] The specifications on this databook are only given for information, without any guarantee as regards either mistakes or omissions. The application circuits in this databook are described only to show representative usages of the product and not intended for the guarantee or permission of any right including the industrial rights. -13-