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| NJM2552 100MHz INPUT MIXER AND 450kHz FM/AM IF DEMODULATOR IC ! GENERAL DESCRIPTION ! PACKAGE OUTLINE The NJM2552 is a FM IF demodulator IC with 450kHz (standard) IF input, which operates from 2.2V to 9.0V supply. It includes an oscillator, mixer, limiting amplifier, FM/AM detectors, and RSSI circuit. The NJM2552 is suitable for FM /AM receivers for data / voice radio systems. NJM2552V ! FEATURES # # # # # Wide Operating Voltage Low Operating Current 2.2V to 9.0V FM: 2.5mA at V+ =2.7V, AM SW =LOW AM and FM: 5mA at V+ =2.7V, AM SW =HIGH 100MHz (reference value) 450kHz (standard) # # # # Maximum Mixer Input Frequency IF Frequency AM/FM detector circuits selectable AM SW= HIGH Simultaneous operation of AM/FM sections AM SW= LOW FM section only Built-in AGC circuit in AM section Wide Range RSSI (Received Signal Strength Indication) Bipolar Technology Package Outline SSOP20 ! BLOCK DIAGRAM MIX IN 20 AM AGC RF AGC IN OUT 18 17 RSSI OUT 16 AM SW 15 AM AF OUT 14 AM DET AMP OUT 13 AMP IN 12 FM AF OUT 11 V+ 19 -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 FM IF IN 8 FM DEC FM AMP FM DET 1 OSC (B) 2 OSC (E) 3 MIX OUT 4 GND 5 AM IF IN 6 AM DEC 9 FM IF OUT 10 QUAD IN Ver.2007-10-24 -1- NJM2552 ! ABSOLUTE MAXIMUM RATINGS PARAMETER SYMBOL V+ Pd Topr Tstg RATINGS 12 300 -40 to +85 - 50 to +125 (Ta=25C) UNIT V mW C C (Ta=25C) CONDITIONS MIN. 2.2 TYP. 2.7 MAX. 9.0 UNIT V Supply Voltage Power Dissipation Operating Temperature Storage Temperature ! RECOMMENDED OPERATING CONDITION PARAMETER SYMBOL V+ Supply Voltage ! ELECTRICAL CHARACTERISTICS Ta=25C, V =2.7V, fMIX=10.7MHz, fLO=10.25MHz, fIF=450kHz, + FM: fdev=3kHz, fmod=1kHz, AM SW=LOW AM: AM=30%, fmod=1kHz, AM SW=HIGH, unless otherwise noted. PARAMETER Current Consumption Current Consumption Mixer Conversion Gain Mixer 3 rd Order Intercept Mixer Input Resistance Mixer Input Capacitance Mixer Output Resistance [FM IF Section] SINAD 12dB Demodulated Output Level 1 Total Harmonic Distortion 1 Signal to Noise Ratio 1 AM Rejection Ratio SINAD V od1 THD1 S/N1 AMR Mixer input, Circuit 2 fIF input, Circuit 4 VinIF =80dBuV fIF input, Cricuit4 VinIF =80dBuV fIF input, Circuit4 VinIF=80dBuV fIF input, Circuit4 VinIF=80dBuV AM=30% 55 43 , 30 5 80 1 60 40 105 2 dBuV mVrms % dB dB SYMBOL Iccq1 Iccq2 Gmix IIP3 R in M Cin M R oM CONDITIONS No signal, Circuit 1 AM SW=HIGH No signal, Circuit 1 AM SW=LOW VinMIX=40dBuV, Pin3 with ceramic filter and 1.8k terminated. Circuit5 Circuit5 MIN. 18 TYP. 5 2.5 22 95 3.6 3.2 1.8 MAX. 6.6 3.1 26 UNIT mA mA dB dBuV k pF k Ver.2007-10-24 -2- NJM2552 PARAMETER FM IF Amp. Input Impedance RSSI Output Voltage 1 RSSI Output Voltage 2 RSSI Output Voltage 3 FM IF Amplifier RF AGC Output Voltage [AM IF Section] Demodulated Output Level 2 Total Harmonic Distortion 2 Total Harmonic Distortion 3 Signal to Noise Ratio 2 Demodulated Output Deviation AM IF Amplifier Input Impedance [AMP Section] Amplifier Gain Gv 31kHz, Circuit 3 47 dB V od2 THD2 THD3 S/N2 D V od RinAMIF fIF input, Circutit4 VinIF =80dBuV AGC On fIF input, Cricuit4 VinIF =60dBuV AGC On fIF input, Cricuit4 VinIF =60dBuV,AM80% AGC On fIF input, Circutit4 VinIF =80dBuV AGC On fIF input, Cricuit4 VinIF =80 to 90dBuV AGC On DC value 42 40 60 1 2 44 1.5 8 10 12 85 3 4 mVrms % % dB dB k SYMBOL RinFMIF Vrssi1 Vrssi2 Vrssi3 FMIFGV V AGC CONDITIONS DC value fIF input, Circuit4 No input signal fIF input, Circuit4 VinIF=60dBuV fIF input, Circuit4 VinIF=100dBuV fIF input, Circuit4 fIF input, Circuit4 VinIF =80dBuV MIN. 1.2 0.8 1.8 0.75 TYP. 1.8 0.1 1.1 2.1 120 1.05 MAX. 2.4 0.4 1.4 2.4 1.35 UNIT k V V V dB V ! AM SW pin select mode Control Voltage 0V to 0.3V(LOW) 0.8V to V+ (HIGH) FM section On On AM section Off On Other sections On On Ver.2007-10-24 -3- NJM2552 ! TEST CIRCUIT This test circuit allows the measurement of all parameters described in "ELECTRICAL CHARACTERISTICS". This test circuit includes some electrical switches that should be in the suitable position for the measurement of each parameter. # Circuit 1 (Iccq1, Iccq2) MIX IN Iccq1 Iccq2 V+ C15 10u C14 0.1u AM AGC RF AGC IN OUT RSSI OUT V+ AM SW AM AF OUT AMP OUT AMP IN FM AF OUT C16 20 19 10u 18 C8 1000p 17 C7 1000p 16 15 AM DET 14 13 R4 270k 12 11 -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 C4 68n C5 0.1u 8 FM AMP FM DET 1 C1 1000p 2 3 4 5 C3 68n 6 9 C6 0.1u 10 V+ R10 LOCAL IN 1.5k # Circuit 2 (SINAD) MIX IN 10.7 MHz V+ AM AGC RF AGC IN OUT RSSI OUT V+ AM SW AM AF OUT AMP OUT AMP IN FM AF OUT BPF SINAD 0.1k to 30k R4 270k R9 10k 12 11 C12 0.01u R2 51 20 C2 1000p 19 C16 10u 18 C8 1000p 17 C7 1000p 16 15 AM DET 14 13 -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 C4 68n C5 0.1u 8 FM AMP FM DET 1 C1 1000p 2 3 4 5 C3 68n CERAMIC FILTER 6 9 C6 0.1u C13 18p R10 1.5k 10 V+ CD C17 10u LOCAL IN 10.25 MHz Ver.2007-10-24 -4- NJM2552 # Circuit 3 (Gv) Gv MIX IN V+ AM AGC RF AGC IN OUT RSSI OUT V+ AM SW C9 1u R4 270k 20 19 18 17 16 15 AM DET 14 13 12 11 AM AF OUT AMP OUT AMP IN C10 1u R5 1k FM AF OUT 31kHz -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 8 FM AMP FM DET 1 C1 1000p LOCAL IN 2 3 4 5 6 9 10 # Circuit 4 (Vod1/2, THD1/2/3, S/N1/2, AMR, Vrssi1/2/3, FMIFGV, VAGC, DVod ) BPF Vod2 DVod THD2 S/N2 THD3 AMP OUT AMP IN FM AF OUT VAGC Vrssi MIX IN V+ AM AGC RF AGC IN OUT R3 20k C16 20 19 10u 18 C8 1000p 17 C7 1000p 16 15 RSSI OUT V+ 0.1k to 30k AM AF OUT R8 8.2k C11 0.01u 14 AM DET 13 12 Vod1 THD1 S/N1 AMR R9 10k 11 C12 0.01u -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 C4 68n C5 0.1u 8 FM AMP FM DET 1 C1 1000p 2 3 4 5 C3 68n 6 9 C6 0.1u C13 18p R10 1.5k 10 V+ CD C17 10u LOCAL IN 450kHz 51 FMIFGV Ver.2007-10-24 -5- NJM2552 # Circuit 5 (Gmix) 10.7MHz MIX IN V+ AM AGC RF AGC IN OUT RSSI OUT V+ AM SW R2 51 20 C2 1000p 19 18 17 16 15 AM DET 14 13 12 11 AM AF OUT AMP OUT AMP IN FM AF OUT -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 8 FM AMP FM DET 1 C1 1000p 2 3 4 5 6 9 10 LOCAL IN 10.25MHz CERAMIC FILTER Gmix 1.8k Ver.2007-10-24 -6- NJM2552 ! TERMINAL FUNCTION (Ta=25C , V+=2.7V , circuit 1) Pin No. SYMBOL V+ EQUIVARENT CIRCUIT VOLTAGE FUNCTION Oscillator Base / Oscillator Emitter Colpitts - type oscillator is formed with an external oscillator element of crystal unit or SAW resonator. Output of an external oscillator circuit can also input to pin1 or pin2. 1 OSC (B) 22k 1 2 2k 2.66V 2 OSC (E) GND 170u 1.95V V+ 200k 20p Mixer Output An external 450kHz ceramic filter is connected. The typical output impedance is 1.8k. 1.75V 3 MIX OUT 3 1.4k 135u GND 4 GND V+ - -- Ground AM IF Input This is an AM IF signal input to AGC amplifier. The typical input impedance is 10k. 5 AM IF IN 5 6 10k 25u 1.35V 6 AM DEC GND 1.24V 1.35V AM IF Decoupling This is an AM IF decoupling terminal for AGC amplifier. An external decoupling capacitor is connected to enhance stability. IF Limiter Amplifier Input This is an input to the IF amplifier after passing through 450kHz ceramic filter. The typical input impedance is 1.8k. IF Decoupling An external decoupling capacitor is connected to enhance stability. V+ 7 FM IF IN 7 8 51k 0.9k 2.66V 0.9k 8 2k FM DEC GND 80u 2.66V Ver.2007-10-24 -7- NJM2552 Pin No. SYMBOL EQUIVARENT CIRCUIT V+ VOLTAGE FUNCTION FM IF Output This is an output of FM IF signal passing though the internal FM amplifier. An external phase - shifting capacitor is connected between pin9 and pin10. 9 FM IF OUT 9 95u GND 1.80V V+ 400 400 Quadrature Detector Input An external phase - shifting coil or ceramic discriminator is connected. 2.70V 10 QUAD IN 10 20u GND V+ FM Demodulated Signal Output An external 3rd order multiple feed -back filter (RC filter) is connected. 95u 100k 10p 11 FM AF OUT 11 0.96V GND V+ 12 AMP IN 20u 0.66V Input of Amplifier for Low Pass Filter External RC components form a low pass filter between pin12 and pin13. This terminal is biased from pin 11 though an external RC filter. Output of Amplifier for Low Pass Filter 12 13 13 AMP OUT 7.3k GND 0.71V Ver.2007-10-24 -8- NJM2552 Pin No. SYMBOL EQUIVARENT CIRCUIT V+ VOLTAGE FUNCTION AM Demodulated Signal Output An external RC filter may be connected to reduce undesired signal. 100u 14 AM AF OUT 14 1.46V GND AM Section ON /OFF Switch Both of AM and FM section are in action during AM SW=HIGH. When AM SW=LOW, AM section keeps a state of not working. 15 AM SW 15 GND 50k -- V+ 2k 2k 2k 2k Received Signal Strength Indicator Output Pin 16 outputs DC level proportional to the log of input signal level to pin7. 0.17V 16 RSSI OUT 16 55k GND V+ 2k Output of RF AGC circuit Pin 17 outputs DC voltage to control the gain of external RF amplifier. 0.08V 17 RF AGC OUT 17 120k GND Ver.2007-10-24 -9- NJM2552 Pin No. SYMBOL V+ EQUIVARENT CIRCUIT VOLTAGE FUNCTION Gain Control of AGC Circuit for AM Signal Pin 18 is connected with pin 14 through the external ripple filter of R and C. 18 AM AGC IN 18 1k 1.46V 25u GND 25u 1.51 19 V+ V+ Supply Voltage Mixer Input The mixer is designed to work up to 100MHz with the typical input impedance of RinM = 3.6k and CinM = 3.2pF(at 10.7MHz). 0.94V 3.6k 50 25p GND 1k 1k 0.94 20 MIX IN 20 3.6k Note : 1. ESD protection diodes exist between each of the following pins and V+. Pin 1,2,3,5,6,7,8,9,10,11,12,13,14,16,17,18,20 2. ESD protection diodes also exist between each of the following pins and ground. Pin 1,2,3,5,6,7,8,9,10,11,12,13,14,15,16,17,18,20 Ver.2007-10-24 - 10 - NJM2552 ! EVALUATION PC BOARD The evaluation board is useful for your design and to have more understanding of the usage and performance of this device. This circuit is the same as TEST CIRCUIT. Note that this board is not prepared to show the recommendation of pattern and parts layout. # Circuit Diagram MIX IN V+ C15 10u R2 51 C2 C14 AM AGC RF AGC IN OUT R3 20k C8 1000p 17 RSSI OUT AM AF OUT V+ R8 8.2k AMP OUT AMP IN C10 FM AF OUT C9 1u R4 270k 13 12 1u R5 1k R9 10k 11 C12 0.01u 0.1u C16 10u 18 C7 1000p 16 15 C11 0.01u 14 AM DET 1000p 20 19 -A AMP RSSI MIXER OSC AMP AGC +- AM AMP + 7 C4 68n C5 0.1u 8 FM AMP FM DET 1 C1 1000p 2 3 4 5 C3 68n CERAMIC FILTER 6 9 C6 0.1u C13 18p R10 1.5k 10 V+ CD C17 10u LOCAL IN Note: 1. External Components R1=R6=R7=0 R2=51 R3=20k R4=270k R5=1k R8=8.2k R9=10k R10=1.5k C1=C2=C7=1000pF C3=C4=68nF C5=C6=C14=0.1uF C9=C10=1uF C11=C12=0.01uF C13=18pF C15=C16=C17=10uF CF=CFWCA450KEFA-R0 (Murata manufacturing Co., Ltd.) CD=CDBCB450KCAY72-R0 (Murata manufacturing Co., Ltd.) Ver.2007-10-24 - 11 - NJM2552 # Circuit Side View LOCAL IN (OSC(B)) RF IN (MIX IN) R2 R1 C2 C1 R3 C7 RF AGC OUT RSSI OUT NJM2552 C3 C4 C6 C13 R4 C5 R5 C9 C8 R6 R8 C11 CD R9 HIGH OFF AM SW ON R7 R10 C10 LOW C12 AM AF OUT NJM2552 GND V+ V + FM AF OUT AMP IN AMP OUT # Ground Side View C16 + C14 C15 + CF C17 + Ver.2007-10-24 - 12 - NJM2552 ! Description # AM AGC Line 1. Example of external circuit C16 10u + R3 20k AM AF OUT FM AF OUT AM AGC Line 20 19 18 17 16 15 14 13 12 11 AGC IN AM DET -A AMP RSSI MIXER OSC AMP AGC +- AM AMP AM IF + 6 7 8 FM AMP FM DET 1 2 3 4 5 9 10 CERAMIC FILTER # Explanation AM AGC IN terminal (pin18) is usually connected with the AM DET terminal (pin 14) through the ripple filter of R3 and C16. This filter has the time constant of R3xC16 and this value of time constant is generally selected to be 5 to 10 times larger than the lowest cycle of the AM modulation signal (, not AM demodulated signal). AGC IN terminal (pin 18) can also be controlled by an external DC source instead of DC output of AM DET terminal. RF AGC Line RF AGC Line + + V+ V+ V 1. Example of external circuit V RF IN Tr3 Tr2 2. RF Amplifier 20 19 18 17 16 MIX IN V V+ + 2k from IF Am p RF AGC OUT Tr1 127k 120k 2. Explanation RF AGC OUT terminal (pin17) can be connected to the bias circuit of the external RF amplifier to control its gain. RF AGC characteristics are shown on following page. Ver.2007-10-24 - 13 - NJM2552 ! TYPICAL CHARACTERISTICS Ta=25C, V =2.7V, fMIX=10.7MHz, fLO=10.25MHz, fIF=450kHz FM: fdev=3kHz, fmod=1kHz, AM SW=LOW AM: AM=30%, fmod=1kHz, AM SW=HIGH, unless otherwise noted. + [DC Characteristics] Current Consumption versus Supply Voltage 8 Current Consumption Iqq(mA) circuit 1, no signal Current Consumption versus Temperature 8 circuit 1, no signal 7 6 5 4 Iccq2 3 2 1 0 0 2 4 6 8 + Current Consumption Iqq(mA) 7 6 5 4 3 2 1 0 Iccq2 Iccq1 Iccq1 10 12 -50 -25 0 25 50 75 100 125 Supply Voltage V (V) Ambient Temperature Ta(C) Current Consumption versus AM SW Voltage 8 circuit 1, no signal Current Consumption Iccq(mA) 7 6 5 4 3 2 1 0 0 0.5 1 1.5 2 2.5 3 Low AM SW : High AM SW Control Voltage (V) Ver.2007-10-24 - 14 - NJM2552 [Mixer Characteristics] Mixer Conversion Gain versus Frequency and Supply Voltage 30 Mixer Conversion Gain Gmix(dB) circuit 5, VinMIX=40dBuV, VinLO=100dBuV Mixer Conversion Gain versus Frequency and Temperature 30 Mixer Conversion Gain Gmix(dB) circuit 5 , VinMIX=40dBuV , VinLO=100dBuV 25 V+=9V V+=2.7V 25 Ta=25C 20 Ta=- 40C Ta=85C 15 20 V =2.2V 15 + 10 10 100 Mixer Input Frequency fMIX(MHz) 1000 10 10 100 Mixer Input Frequency fMIX(MHz) 1000 Mixer 3rd Order Intermodulation 120 circuit 5, VinLO=100dBuV Mixer Conversion Gain vesus Local Input Level 25 circuit 5, VinMIX=40dBuV 1dB Comp.Pt. 100 80 60 40 20 0 0 20 40 60 80 100 120 IIP3 Mixer Conversion Gain Gmix(dB) Mixer Output Level (dBuV) 20 15 Ta=- 40C 10 Ta= 25C 5 Ta=85C 0 40 60 80 100 120 Desired Products 3rd Order Intermod. Products Mixer Input Level VinMIX(dBuV) Local Input Level VinLO(dBuV) Ver.2007-10-24 - 15 - NJM2552 [RSSI Characteristics] RSSI Output versus IF Input and Supply Voltage 3 circuit 4 RSSi Output versus IF Input and Ambient Temperature RSSI Output Voltage Vrssi(V) V = 9V + 3 2.5 2 circuit 4 RSSI Output Voltage Vrssi(V) 2.5 2 2.7V 2.2V Ta=85C, 25C - 40C 1.5 1 0.5 0 1.5 1 0.5 0 -20 0 20 40 60 80 100 120 -20 0 20 40 60 80 100 120 IF Input Level VinIF(dBuV) IF Input Level VinIF(dBuV) RSSI Output versus Mixer Input and Supply Voltage 3 circuit 2 , VinLO=100dBuV RSSI Output versus Mixer Input and Ambient Temperature 3 circuit 2 , VinLO=100dBuV RSSI Output Voltage Vrssi(dB) RSSI Output Voltage Vrssi(V) V = 9V 2.5 2 V+=2.2V 1.5 1 0.5 0 -20 0 20 40 60 80 100 120 V =2.7V + + 2.5 2 Ta=85C, 25C - 40C 1.5 1 0.5 0 -20 0 20 40 60 80 100 120 Mixer Input Level VinMIX(dBuV) Mixer Input Level VinMIX(dBuV) RSSI Output versus Temperature and IF Input Level 3 RSSI Output Voltage Vrssi(V) circuit 4 2.5 2 1.5 1 0.5 0 -50 -25 0 100dBuV VinMIX=120dBuV 90dBuV 80dBuV 70dBuV 60dBuV 50dBuV 40dBuV - 20dBuV 25 50 75 100 125 Ambient Temperature Ta(C) Ver.2007-10-24 - 16 - NJM2552 [RF AGC Characteristics] RF AGC Output versus IF Input and Supply Voltage 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 circuit 4 RF AGC Output versus IF Input and Ambient Temperature 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 circuit 4 RF AGC Output Voltage VAGC(V) V+=9.0V RF AGC Output Voltage VAGC(V) 2.7V 2.2V Ta=85C, 25C, - 40C 0 20 40 60 80 100 120 -20 0 20 40 60 80 100 120 IF Input Level VinIF(dBuV) IF Input Level VinIF(dBuV) RF AGC Output versus Mixer Input and Supply Voltage 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 circuit 2 , VinLO=100dBuV RF AGC Output versus Mixer Input and Ambient Temperature 2.4 2.2 2 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 circuit 2 , VinLO=100dBuV RF AGC Output Voltage (V) RF AGC Output Voltage (V) V+=9.0V 2.7V 2.2V Ta=85C, 25C, - 40C -20 0 20 40 60 80 100 120 -20 0 20 40 60 80 100 120 Mixer Input Level VinMIX(dBuV) Mixer Input Level VinMIX(dBuV) RF AGC Output versus Temperature and IF Input Level 2 RF AGC Output Voltage VAGC(V) circuit 4 VinMIX=120dBuV 90dBuV 85dBuV 80dBuV 1.8 1.6 1.4 1.2 1 0.8 0.6 0.4 0.2 0 -50 -25 0 75dBuV 70dBuV - 20dBuV 25 50 75 100 125 Ambient Temperature Ta(C) Ver.2007-10-24 - 17 - NJM2552 [FM Demodulation Characteristics] FM AF OUT Voltage versus Frequency and Supply Voltage (S-Curve) 2.5 FM AF OUT Voltage(V) 2 1.5 1 0.5 0 420 430 440 450 460 470 480 V+=2.7V 2.2V circuit 4 , VinIF=80dBuV FM AF OUT Voltage versus Frequency and Ambient Temperature (S-Curve) 2.5 circuit 4 , VinIF=80dBuV V+=9.0V FM AF OUT Voltage(V) 2 Ta=85C 1.5 Ta=- 40C 1 0.5 0 420 430 440 450 460 470 480 Ta= 25C IF Input Frequency fIF(kHz) IF Input Frequency fIF(kHz) FM Demod. Output versus FM Modulation Frequency 200 180 circuit 4, VinIF=80dBuV FM Demod.Output and Distortion -IF Detuning Characteristics1000 FM Demodulated Output Level1 Vod1(mVrms) circuit 4 , VinIF=80dBuV 1000 FM Demodulated Output Level1 Vod1(mVrms) 140 120 100 80 60 40 20 0 0.1 1 10 100 10 THD1 10 1 1 0.1 430 440 450 460 0.1 470 FM Modulation Frequency fmod(kHz) IF Input Frequency fIF(kHz) FM : S+N, N, AMR, SINAD, THD1 versus Mixer Input Level 10 0 circuit 2 , VinLO=100dBuV FM : S+N, N, AMR, SINAD, THD1 versus IF Input Level 80 10 0 SINAD(dB), THD1(%) circuit4 80 S+N 70 60 SINAD 50 40 AMR N 30 20 10 THD1 0 100 120 S+N 70 -20 SINAD -30 -40 -50 -60 THD1 -70 -20 0 20 40 60 80 N AMR 50 40 30 20 10 0 100 120 S+N, N, AMR (dB) S+N, N, AMR (dB) -10 60 -10 -20 -30 -40 -50 -60 -70 -20 0 20 40 60 80 Mixer Input Level VinMIX(dBuV) IF Input Level VinIF(dBuV) Ver.2007-10-24 - 18 - SINAD(dB), THD1(%) Distortion THD1(%) 160 Vod1 100 100 NJM2552 [AM Demodulation Characteristics] AM30% : Demod. Output and Distortion versus IF Input Level 1000 AM Demodulated Output Level Vod2(mVrms) circuit4, AM=30% AM30% : Demod. Output and Distortion versus Mixer Input Level 1000 AM Demodulated Output circuit 2 , VinLO=100dBuV , AM=30% 1000 1000 Vod2 100 100 100 100 10 10 10 10 1 THD2 0.1 -20 0 20 40 60 80 1 1 THD2 0.1 -20 0 20 40 60 1 0.1 100 120 0.1 80 100 120 Mixer Input Level VinMIX(dBuV) IF Input Level VinIF(dBuV) AM30% : S+N, N versus Mixer Input Level 10 0 -10 circuit 2 , VinLO=100dBuV , AM=30% AM30% : S+N, N versus IF Input Level 10 0 -10 circuit4 , AM=30% S+N S+N S+N, N (dB) -20 -30 -40 -50 -60 -70 -20 0 20 40 60 80 100 120 N S+N, N (dB) -20 -30 N -40 -50 -60 -70 -20 0 20 40 60 80 100 120 Mixer Input Level VinMIX(dBuV) IF Input Level VinIF(dBuV) AM30% : Demodulated Output Level versus Supply Voltage 85 80 AM Demodulated Output Level Vod2(mVrms) 75 70 65 60 55 50 45 40 2 4 6 8 + AM30% : Demodulated Output Level versus Ambient Temperature 85 80 circuit4, VinIF=80dBuV, AM=30% circuit 4 , VinIF=80dBuV , AM=30% AM Demodulated Output Level Vod2(mVrms) 75 70 65 60 55 50 45 40 10 12 -50 -25 0 25 50 75 100 125 Supply Voltage V (V) Ambient Temperature Ta(C) Ver.2007-10-24 - 19 - Distortion THD2(%) Level Vod2(mVrms) Distortion THD2(%) Vod2 NJM2552 AM80% : Demod. Output and Distortion versus Mixer Input Level 1000 circuit 2 , VinLO=100dBuV , AM=80% AM80% : Demod. Output and Distortion versus IF Input Level 1000 circuit4, AM=80% 1000 1000 Vod2 AM Demodulated Output AM Demodulated Output Level Vod2(mVrms) Vod2 Level Vod2(mVrms) 100 100 100 100 10 10 10 10 1 THD3 0.1 -20 0 20 40 60 80 1 1 THD3 1 0.1 100 120 0.1 -20 0 20 40 60 0.1 80 100 120 Mixer Input Level VinMIX(dBuV) IF Input Level VinIF(dBuV) AM80% : S+N, N versus Mixer Input Level 10 0 -10 circuit 2 , VinLO=100dBuV, AM=80% AM80% : S+N, N versus IF Input Level 10 0 -10 circui4 , AM=80% S+N S+N S+N, N (dB) -20 -30 -40 -50 -60 -70 -20 0 20 40 60 80 100 120 N S+N, N (dB) -20 -30 -40 N -50 -60 -70 -20 0 20 40 60 80 100 120 Mixer Input Level VinMIX(dBuV) IF Input Level VinIF(dBuV) AM Demodulated Output versus AM Modulation Frequency 100 90 circuit4(BPF less), VinIF=80dBuV, AM=30% AM Demodulated Output versus IF Input Frequency 100 90 AM Demodulated Output Level Vod2(mVrms) 80 70 60 50 40 30 20 10 0 fif=450kHz circuit4, VinIF=80dBuV, AM=30% AM Demodulated Output Level Vod2(mVrms) 80 70 60 50 40 30 20 10 0 0.1 1 10 100 0.1 1 10 100 AM Modulation Frequency fmod(kHz) IF Input Frequency fIF(MHz) Ver.2007-10-24 - 20 - Distortion THD3(%) Distortion THD3(%) NJM2552 [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. Ver.2007-10-24 - 21 - |
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