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| Ordering number : ENN6655 Monolithic Linear IC LA1787M Single-Chip Tuner IC for Car Radios Overview The LA1787M integrates all six blocks required in a car radio tuner on a single chip. * * Functions * FM front end * FM IF * Noise canceller * Multiplex * AM up-conversion * FM/AM switch * MRC * Features * Improved noise reduction methods -- The FM front end provides excellent 3-signal characteristics equivalent to those of the LA1193M. -- Superlative listenability due to improved medium and weak field noise canceller characteristics. -- Improved separation characteristics -- Anti-birdie filter -- Improved AM and FM thermal characteristics * * -- Excellent FM signal meter linearity -- Modified N.C. circuit for improved noise rejection Improved AM adjacent channel interference characteristics (40 kHz) Double conversion AM tuner (up conversion) Reduces the number of external components required as compared to earlier double conversion tuners, in particular, no crystal is required (when used in conjunction with the LC72144). Sample-to-sample variation reduction circuit built into the FM IF circuit. (Fixed resistors are used for the SD, keyed AGC, mute on adjustment, ATT, SNC, and HCC functions.) Improved FM separation temperature characteristics The LA1787 inherits the block arrangement of the LA1780M and supports pin-compatible designs. Package Dimensions Unit:mm 3159A-QIP64E (14 x 14) [LA1787M] 48 49 33 32 0.8 14.0 17.2 14.0 Allowable power dissipation, Pdmax -- mW Independent IC 64 1 0.8 (1.0) (2.7) 0.35 17 16 0.15 3.0max SANYO: QIP64E (14 x 14) Ambient temperature, Ta -- C Any and all SANYO products described or contained herein do not have specifications that can handle applications that require extremely high levels of reliability, such as life-support systems, aircraft's control systems, or other applications whose failure can be reasonably expected to result in serious physical and/or material damage. Consult with your SANYO representative nearest you before using any SANYO products described or contained herein in such applications. SANYO assumes no responsibility for equipment failures that result from using products at values that exceed, even momentarily, rated values (such as maximum ratings, operating condition ranges, or other parameters) listed in products specifications of any and all SANYO products described or contained herein. SANYO Electric Co.,Ltd. Semiconductor Company TOKYO OFFICE Tokyo Bldg., 1-10, 1 Chome, Ueno, Taito-ku, TOKYO, 110-8534 JAPAN 72602RM (OT) No. 6655-1/54 0.1 17.2 Mounted on a 40 x 80 x 1.3 mm3 glass epoxy printed circuit board LA1787M Specifications Maximum Ratings at Ta = 25C Parameter Maximum supply voltage Allowable power dissipation Operating temperature Storage temperature Symbol VCC1 max VCC2 max Pd max Topr Tstg Pins 6, 40, and 61 Pins 7, 45, 54, 59, and 60 Ta 55C Conditions Ratings 9 12 950 -40 to +85 -40 to +150 Unit V V mW C C Operating Conditions at Ta = 25C Parameter Recommended supply voltage Operating supply voltage range Symbol VCC VCCST IND VCC op Conditions Pins 6, 7, 40, 45, 54, 59, 60, and 61 Pin 26 Ratings 8 5 7.5 to 9.0 Unit V V V Operating Characteristics at Ta = 25C, VCC= 8.0V, in the specified test cricuit for the FM IF input Ratings Parameter Symbol Conditions min 60 205 190 -1 typ 94 310 295 0 0.3 75 55 5 15 28 30 1.2 0.6 82 68 10 20 33 40 2.4 1.6 0.3 20 1 0.5 6 33 27 54 54 10.7 MHz, 100 dB, unmodulated. The pin 23 output No input. The pin 24 DC output, unmodulated 50 dB. The pin 24 DC output, unmodulated 70 dB. The pin 24 DC output, unmodulated 100 dB. The pin 24 DC output, unmodulated 100 dB. The bandwidth when V33 = 2 V, unmodulated 100 dB, 0 dB. The pin 33 DC output, unmodulated 130 0.0 0.4 2.0 4.7 150 0.00 30 5 4.5 10 40 35 62 62 200 0.1 1.0 2.7 5.5 220 0.03 9 8.5 14 47 43 70 70 270 0.3 1.5 3.5 6.2 290 0.20 1.2 4.4 15 25 38 max 110 415 380 +1 1 [FM Characteristics] At the FM IF input Current drain Demodulation output Pin 31 demodulation output Channel balance Total harmonic distortion Signal-to-noise ratio: IF AM suppression ratio: IF ICCO-FM VO-FM VO-FM31 CB THD-FM mono S/N-FM IF AMR IF Att-1 Muting attenuation Att-2 Att-3 Separation Stereo on level Stereo off level Main total harmonic distortion Pilot cancellation SNC output attenuation Separation ST-ON ST-OFF THD-Main L PCAN AttSNC AttHCC-1 HCC output attenuation AttHCC-2 Input limiting voltage Muting sensitivity SD sensitivity IF counter buffer output Vi-lim Vi-mute SD-sen1 FM SD-sen2 FM VIFBUFF-FM VSM FM-1 Signal meter output VSM FM-2 VSM FM-3 VSM FM-4 Muting bandwidth Mute drive output BW-mute VMUTE-100 No input, I40 + I45 + I54 + I59 + I60 + I61 10.7 MHz, 100dB, 1 kHz, 100%mod, The pin 15 output 10.7 MHz, 100dB, 1 kHz, 100%mod, The pin 31 output The ratio between pins 15 and 16 at 10.7 MHz, 100 dB, 1 kHz 10.7 MHz, 100 dB, 1 kHz, 100% mod, pin 15 10.7 MHz, 100 dB, 1 kHz, 100% mod, pin 15 10.7 MHz, 100 dB, 1 kHz, fm = 1 kHz, 30% AM, pin 15 10.7 MHz, 100 dB, 1 kHz. The pin 15 attenuation when V33 goes from 0 to 2 V 10.7 MHz, 100 dB, 1 kHz. The pin 15 attenuation when V33 goes from 0 to 2 V*1 10.7 MHz, 100 dB, 1 kHz. The pin 15 attenuation when V33 goes from 0 to 2 V*2 10.7 MHz, 100 dB, L+R = 90%, pilot = 10%. The pin 15 output ratio The pilot modulation such that V26 < 0.5 V The pilot modulation such that V26 > 3.5 V 10.7 MHz, 100 dB, L+R = 90%, pilot = 10%. The pin 15 signal 10.7 MHz, 100 dB, pilot = 10%. The pin 15 signal/the pilot level leakage. DIN audio 10.7 MHz, 100 dB, L-R = 90%, pilot = 10%. V28 = 3 V 0.6 V, pin 15 10.7 MHz, 100 dB, 10 kHz, L+R = 90%, pilot = 10%. V29 = 3 V 0.6 V, pin 15 10.7 MHz, 100 dB, 10 kHz, L+R = 90%, pilot = 10%. V29 = 3 V 0.1 V, pin 15 100 dB, 10.7 MHz, 30% modulation. The IF input such that the input reference output goes down by 3 dB The IF input level (unmodulated) when V33 = 2 V The IF input level (unmodulated) (over 100 mV rms) such that the IF counter buffer output goes on mA mVrms mVrms dB % dB dB dB dB dB dB % % % dB dB dB dB dB dB dB dB mVrms V V V V kHz V unit Continued on next page. No. 6655-2/54 LA1787M Continued from preceding page. Ratings Parameter [FM FE Mixer Input N-AGC on input W-AGC on input Conversion gain Oscillator buffer output [NC Block] NC input (pin 30) Gate time Noise sensitivity GATE1 SN f = 1 kHz, for a 1-s, 100-mV p-o pulse The level of a 1 = kHz, 1-s pulse input that starts noise canceller operation. Measured at pin 30. The pulse rejection effect provided by the noise canceller. For a repeated 1-s wide pulse, frequency = 10 kHz, 150 mV p-o. The ratio of the FM mode pin 15 output referenced to the AM mode pin 15 output (effective value) 55 40 s mVp-o VN-AGC VWAGC A.V VOSCBUFFFM 83 MHz, unmodulated. The input such that the pin 2 voltage is 2.0 V or below 83 MHz, unmodulated. The input such that the pin 2 voltage is 2.0 V or below. (When the keyed AGC is set to 4.0 V.) 83 MHz, 80 dB, unmodulated. The FE CF output No input 81 104 19 85 88 110 30 110 95 116 48 165 dB dB mVrms mVrms Symbol Conditions min typ max unit NC effect SN-NC 5 [Multipath Rejection Circuit] MRC input (pin 27) MRC output MRC operating level VMRC MRC-ON V24 = 5 V The pin 32 input level at f = 70 kHz such that pin 24 goes to 5 V and pin 27 goes to 2 V 2.2 10 2.3 15 2.4 20 V mVrms [AM Characteristics] AM ANT input Practical sensitivity Detector output Pin 31 detector output AGC F.O.M. Signal-to-noise ratio Total harmonic distortion Signal meter output Oscillator buffer output Wide band AGC sensitivity S/N-30 VO-AM VO-AM31 VAGC-FOM S/N-AM THD-AM VSM AM-1 VSM AM-2 VOSCBUFF AM1 W-AGCsen1 W-AGCsen2 SD sensitivity IF buffer output SD-sen1 AM SD-sen2 AM VIFBUFF-AM 1 MHz, 30 dB, fm = 1 kHz, 30% modulation, pin 15 1 MHz, 74 dB, fm = 1 kHz, 30% modulation, pin 15 1 MHz, 74 dB, fm = 1 kHz, 30% modulation, pin 31 1 MHz, 74 dB, referenced to the output, the input amplitude such that the output falls by 10 dB. Pin 15 1 MHz, 74 dB, fm = 1 kHz, 30% modulation 1 MHz, 74 dB, fm = 1 kHz, 80% modulation No input 1 MHz, 130 dB, unmodulated No input, the pin 15 output 1.4 MHz, the input when V46 = 0.7 V 1.4 MHz, the input when V46 = 0.7 V (seek mode) 1 MHz, the ANT input level such that the IF counter output turns on. 1 MHz, the ANT input level such that the SD pin goes to the on state. 1 MHz, 74 dB, unmodulated. The pin 23 output 0.0 4.8 185 92 83 24 24 200 20 130 110 51 47 195 175 56 52 0.3 0.2 6 230 98 89 30 30 290 104 95 36 36 1 0.5 7.3 270 230 61 dB mVrms mVms dB dB % V V mVrms dB dB dB dB mVrms Note: These measurements must be made using the either the IC-51-0644-824 or KS8277 IC socket (manufactured by Yamaichi Electronics). * 1. When the resistor between pin 58 and ground is 200 k. * 2. When the resistor between pin 58 and ground is 30 k. No. 6655-3/54 LA1787M Function List FM Front End (Equivalent to the Sanyo LA1193) * Double input type double balanced mixer * Pin diode drive AGC output * MOSFET second gate drive AGC output * Keyed AGC adjustment pin * Differential IF amplifier * Wide band AGC sensitivity setting pin, and narrow band AGC sensitivity setting pin * Local oscillator FM IF * IF limiter amplifier * S-meter output (also used for AM) 6-stage pickup * Multipath detection pin (shared FM signal meter) * Quadrature detection * AF preamplifier * AGC output * Band muting * Weak input muting * Soft muting adjustment pin * Muting attenuation adjustment pin * IF counter buffer output (also used for AM) * SD (IF counter buffer on level) adjustment pin * SD output (active high) (also used for AM) Noise Canceller * High-pass filter (first order) * Delay circuit based low-pass filter (fourth order) * Noise AGC * Pilot signal compensation circuit * Noise sensitivity setting pin * Function for disabling the noise canceller in AM mode Multiplex Functions * Adjustment-free VCO circuit * Level follower type pilot canceller circuit * HCC (high cut control) * Automatic stereo/mono switching * VCO oscillation stop function (AM mode) * Forced monaural * SNC (stereo noise controller) * Stereo display pin * Anti-birdie filter AM * Double balanced mixer (1st, 2nd) * IF amplifier * Detection * RF AGC (narrow/wide) * Pin diode drive pin * IF AGC * Signal meter output (also used for FM) * Local oscillator circuits (first and second) * Local oscillator buffer output * IF counter buffer output (also used by the FM IF) * SD (IF counter buffer on level) adjustment pin * SD output (active high) (also used for AM) * Wide AGC * Detection output frequency characteristics adjustment pin (low cut, high deemphasis) * AM stereo buffer MRC (multipath noise rejection circuit) AM/FM switching output (linked to the FM VCC) No. 6655-4/54 LA1787M Operating Characteristics and Symbols Used in the Test Circuit Diagrams Switches (SW) Switch on = 1, SW off = 0 There are two switches that use signal transfer. -- SW2: switches between the mixer input and the IF input. -- SW4: switches between noise canceler input and IF output + noise canceler input. Types of SG used PG1 (AC1) AC2 AC3 AC4 AC5 Used for noise canceler testing. A pulse generator and an AF oscillator are required. Used for FM front end testing. Outputs an 83 MHz signal. Used for FM IF, noise canceler, and MPX testing. Outputs a 10.7 MHz signal. Stereo modulation must be possible. Used for AM testing. Outputs 1 MHz and 1.4 MHz signals. Used with the MRC. Can also be used for AF and OSC. Power supply VCC VCC1 VCC2 VCC3 8V 5V 0.1 V / 0.7 V / 2 V / 4 V 0.1 V / 0.6 V / 2 V These levels must be variable. SD, stereo, seek/stop Keyed AGC, Mute ATT HCC, SNC, SASC (MRC) * Switches Parameter SW1 SW2 SW3 SW4 SW5 SW6 SW7 SW8 SW9 SW10 AM/FM switching. The FE VCC is supplied to pin 62. FM IF switching. Pin 51/FE output For conversion gain testing For switching between noise canceler input and IF output + noise canceler. High-speed SD SEEK/STOP (IF BUFF ON/OFF) MUTE ATT 200 k MUTE ATT 30 k For pilot cancellation testing Mute off (pin 33) ON FM FE IF OUT (A) Conversion gain measurement (A) AC1 (A) High-speed SD STOP MUTE 200 k MUTE 30 k When pilot cancellation is used MUTE OFF OFF AM AC3 (B) Other/purposes Other/purposes Other/purposes Seek (IF buffer output) OFF OFF When pilot cancellation is not used MUTE ON * Trimmers (variable resistors) VR1 VR2 Separation adjustment Pilot cancellation adjustment Test Points * DC voltages VD1 VD2 VD3 VD4 VD5 VD6 VD7 FM RF AGC voltage AM/FM SD, AM Tweet, FM stereo indicator AM/FM S-meter MRC output Mute drive output AM antenna damping voltage N.C. Gate time Pin 2 Pin 26 Pin 24 Pin 27 Pin 33 Pin 46 Pin 8 * AC voltages VA1 VA2 VA3 VA4 VA5 AM/FM OSC Buff First IF output IF counter buffer MPX OUT Left ch MPX OUT Right ch Pin 4 Pin 53 CF pin 51 load level (10.7 MHz) Pin 23 (10.7 MHz/450 kHz) Pin 15 (AF) Pin 16 (AF) No. 6655-5/54 LA1787M Pin Descriptions Pin No. Function Description Equivalent circuit VCC ANT RF AGC 62 pin 1 Antenna damping drive An antenna damping current flows when the RF AGC voltage (pin 2) reaches VCC - VD. 1000pF 100 1 100 1000pF 300 A13555 VCC FET 2nd GATE 12k 2 DAMPING DRIVER 2 RF AGC Used to control the FET second gate. + ANT N AGC DET KEYED AGC W AGC DET VCC A13556 3 F.E.GND VCC 4 4 OSC Oscillator connection 25pF VT 2k 20pF A13557 7 VCC 7 AM OSC AM first oscillator This circuit can oscillator up to the SW band. An ALC circuit is included. ALC A13558 Continued on next page. No. 6655-6/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit 3k 3k 15k 8 9 Noise AGC sensitivity AGC adjustment After setting up the medium field (about 50 dB) sensitivity with the noise sensitivity setting pin (pin 8), set the weak field (about 20 to 30 dB) sensitivity with the AGC adjustment pin (pin 9) 8 200 9 3k 0.01F 1M + 0.47F A13559 0.01F 6800pF 3.9k 13 12 VCC 11 11 12 Memory circuit connection Recording circuit used during noise canceller operation. Differential amp Gate circuit LPF A13560 VCC 30k 13 Pilot input Pin 13 is the PLL circuit input pin. PLL N.C 12 13 0.01F A13561 14 N.C, MPX, MRC, GND Ground for the N.C., MPX, and MRC circuits. Continued on next page. No. 6655-7/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit VCC 15 16 MPX output (left) MPX output (right) Deemphasis 50 s: 0.015 F 75 s: 0.022 F 3.3k 3.3k 15 0.015F 16 0.015F A13562 VCC 20k 17 Pilot canceller signal output Adjustment is required since the pilot signal level varies with the sample-to-sample variations in the IF output level and other parameters. 10k 6.7k 17 0.01F 100k 18 A13563 VCC 18 Pilot canceller signal output Pin 18 is the output pin for the pilot canceller signal. 1.5k 17 0.01F 100k 18 A13564 Continued on next page. No. 6655-8/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit DECODER Composite signal 5k 19 Separation adjustment pin Use a trimmer to adjust the subdecoder input level. (The output level is not modified in mono and main modes.) 4k 19 30k 0.047F A13565 CSB 912 JF108 20 VREF 20 VCO The oscillator frequency is 912 Hz. KBR-912F108 (Kyocera Corporation) CSB-912JF108 (Murata Mfg. Co., Ltd.) 10pF A13566 VREF 21 22 PHASE COMP. PHASE COMP. + 15k 15k 19k 21 + + 22 A13567 Continued on next page. No. 6655-9/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit 4.9V + - 50k + - AM MUTE VCC IF counter buffer 1.3V 10k 23 IF counter buffer seek/stop switching This pin functions both as the IF counter buffer (AC output) and as the seek/stop switch pin. The voltage V23 switches between the following three modes. During FM reception: 5 V: Seek mode 2.5 V: Forced SD mode 0 V: Reception mode AM reception (two modes: 0 and 5 V) 5 V: Seek mode 0 V: Reception mode SW + - 150 50F SD 23 51k STOP IF BUFF. Forced SEEK SD: 2.5V 5V A13568 VCC FM S-meter 24 AM/FM signal meter Fixed-current drive signal meter output In AM mode, pin 32 outputs a 1-mA current. Thus the HCC circuit is turned off. AM S-meter 10k 32 10k 24 AM/FM SW 32 Dedicated FM signal meter Outputs a 1-mA current during AM reception MRC AM/FM SW A13569 26 Stereo indicator for the SD pin The voltage V23 switches between three modes as follows. FM reception: 5 V: The SD pin operates linked to the IF counter buffer. 2.5 V: Forced SD mode: operates as the SD pin. 0.7 V: Reception mode: stereo indicator AM reception: (two modes: 0 and 5 V) 5 V: Operates as the seek SD pin. 0 V: Reception mode. Not used. AM/FM SD Stereo indicator Seek/stop switching 26 100k VDD A13570 Continued on next page. No. 6655-10/54 LA1787M Continued from preceding page. Pin No. Function Description VCC VCC 2A Equivalent circuit 27 27 MRC control voltage time constant The MRC detector time constant is determined by a 100 resistor and C2 when discharging and by the 2-A current and C2 when charging. 100 + C2 Pin 28 A13571 VREF 28 SNC control input The sub-output is controlled by a 0 to 1-V input. 28 A13572 VREF The high band frequency output is controlled by a 0 to 1-V input. It can also be controlled by the MRC output. Use a resistor of at least 100 k when controlling with the pin 32 FM S-meter signal. 32 29 + 29 HCC control input 1F A13573 Continued on next page. No. 6655-11/54 LA1787M Continued from preceding page. Pin No. Function Description VCC FM detector output 31 Equivalent circuit 30 Noise canceller input Pin 30 is the noise canceller input. The input impedance is 50 k. Pin 31 is the AM and FM detector output In FM mode, this is a lowimpedance output. In AM mode, the output impedance is 10 k. To improve the low band separation, use a coupling capacitor of over 10 F. VCC AM detector 10k 1F + 31 AM/FM detector output 30 Noise canceller 50k 4.2V A13574 VCC 32 32 IF S-meter output and MRC DC input FM S-meter output block MRC AC input block Adjust the external 1-k resistor to attenuate the MRC AC input and control the circuit. 10k + 1F 1k MRC input A13575 C1 + 0.1F *The muting time constant is determined by an external RC circuit as described below. Attack time: TA = 10 k x C1 Release time: TR = 50 k x C1 *Noise convergence adjustment The noise convergence can be adjusted when there is no input signal by inserting a resistor between pin 33 and ground. *Muting off function Ground pin 33 through a 4-k resistor. 33 VCC 50k MUTE AMP. SEEK OFF 10k 33 Mute drive output SOFT MUTE HOLE DET Band muting 50k SD circuit A13576 Continued on next page. No. 6655-12/54 LA1787M Continued from preceding page. Pin No. Function Description 0.1F VCC C VREF Equivalent circuit R1 37 R2 36 35 34 *The resistor R1 determines the width of the band muting function. Increasing the value of R1 narrows the band. Reducing the value of R1 widens the band. 34 35 36 37 AGC QD output QD input VREF *Null voltage When tuned, the voltage between pins 34 and 37, V34 - 37, will be 0 V. The band muting function turns on when |V34 - 37| 0.7 V. V37 = 4.9 V VCC Quadrature detector HOLE DET 3pF 390 1k IF limitter amplifier Band muting A13577 R SD ADJ 38 38 FM SD ADJ A 130-A current flows from pin 38 and, in conjunction with the external resistance R, determines the comparison voltage. 130A + - SD Comparator 24 S-meter A13578 S-meter 6.4k 3.6k 24 39 Keyed AGC AM stereo buffer The keyed AGC operates when the voltage created by dividing the pin 24 S-meter output voltage by the 6.4 and 3.6 k resistors becomes lower than the voltage determined by the resistor between pin 39 and ground. This pin also is used as the AM stereo IF buffer pin. Comparator KEYED AGC + - 39 90A 1.3V VCC AM IF out 50pF 150 A13579 Continued on next page. No. 6655-13/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit VCC 20k + 20k 41 HCC capacitor The HCC frequency characteristics are determined by the external capacitor connected at this pin. 41 2200pF A13580 This pin is used to change the frequency characteristics of the unneeded audio band under 100 Hz in AM mode to produce a clear audio signal. Note: The LC capacitor must be connected between this pin and VCC (pin 40). This is because the detector circuit operates referenced to VCC. The cutoff frequency fC is determined by the following formula. fC = 1/2 x 50 k x C VCC VCC C 42 42 AM L.C. pin DET 50k 1k + - 50k 1k A13581 VCC 19kHz0 BIAS 30k 43 Pilot detector Inserting a 1-M resistor between pin 43 and VCC will force the IC to mono mode. 30k + 30k 43 1F + A13582 Continued on next page. No. 6655-14/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit VCC C 2.2F + 0.022F 240k 42 44 44 IF AGC G1; Used for time constant switching during seeks. * Reception = 2.2 F x 300 k * Seek = 2.2 F x 10 The external capacitors are connected to VCC. This is because the IF amplifier operates referenced to VCC. VCC DET 50k 50k IF AGC G1 SEEK ON 10 A13583 Pin 40 VCC 45 Pin 40 VCC 45 IF output The IF amplifier load DET A13584 VCC 50pF 46 100 46 AM antenna damping drive output Wide band AGC input I46 = 6 mA (maximum) This is the antenna damping current. VCC 20k W.AGC AMP. ANT DAMPING DRIVER A13585 Continued on next page. No. 6655-15/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit 30k R 47 VCC 47 FM muting on level adjustment Modify the value of the external resistor to adjust the muting on level. 140A Pin 24 VCC 5.6V 48 57 RF AGC bypass RF AGC RF AGC rectification capacitor The low frequency distortion is determined as follows: Increasing C48 and C57 improves the distortion but makes the response slower. Reducing C48 and C57 aggravates the distortion but makes the response faster. 48 + 3.3F For AGC use 57 + 47F A13587 2.6V 10k 50 330 51 10k 50 51 IF bypass FM IF input Due to the high gain of the limiter amplifer, care must be taken when choosing the grounding point for the limiter amplifer input capacitor to prevent oscillation. 0.022F IF in A13588 52 IF input The input impedance is 2 k. 52 + - Inverter MUTE A13586 10k + - Antenna damping 2k 100 A13589 Continued on next page. No. 6655-16/54 LA1787M Continued from preceding page. Pin No. Function Description Equivalent circuit VCC IF OUT 53 * Input and output pin or the first IF amplifier * Inverting amplifier 53 56 IF amplifier output IF amplifier input V56 = 2 V Input impedance: RIN = 330 V53 = 5.3 V Output impedance ROUT = 330 IF IN 56 2.75V 300 300 A13590 Pin 40 VCC Pin 40 VCC 54 54 49 Mixer output: 130 A Mixer input The mixer coil connected to the pin 54 mixer output must be wired to VCC (pin 40). The pin 49 mixer input impedance is 330 49 OSC 330 A13591 62 pin VCC W-AGC N-AGC Pins 55 and 58 include built-in DC cut capacitors. The AGC on level is determined by the values of the capacitors C1 and C2. 55 W-AGC IN AM SD ADJ N-AGC IN Muting attenuation adjustment pin Pin 55 functions as the SD sensitivity adjustment pin in AM mode. The output current I55 is 50 A, and V55 varies depending on the value of the external resistor. The SD function operates by comparing V55 with the S-meter voltage. 30pF 55 C1 58 50pF MIX IN 58 C2 50A MIX OUT + - AM SD Signal meter A13592 Continued on next page. No. 6655-17/54 LA1787M Continued from preceding page. Pin No. Function Description 1ST.IF Equivalent circuit OSC 59 Double balanced mixer Pins 59 and 60 are the mixer 10.7-MHz output 59 60 60 VCC Mixer output 63 64 Mixer input Pins 63 and 64 are the mixer input. This is an emitter insertion type circuit, and the amount of insertion is determined by the capacitors C1 and C2. Note:The lines for pins 63 and 64 must be kept separated from the lines for pins 59 and 60. 30 VCC C1 63 RF AMP 5pF C2 64 5pF 620 620 A13593 Pin 6 functions both as the FM front end VCC and the AM/FM switching circuit. 6 Front end VCC AM/FM switching V6 voltage Mode SD + VCC 6 510 + - AM/FM switching circuit FM.F.E AGC 100k 8V 3 GND When 8 V FM OPEN AM 3.3V A13594 AM 1st MIX to RF Amp. 62 62 1st MIX INPUT First mixer input The input impedance is about 10 k. 2.1V 10k A13595 10k 5.6V 20pF to 2nd MIX 10 AM 2nd OSC Crystal oscillator circuit The Kinseki, Ltd. HC-49/U-S and a CL of 20 pF must be used. 33pF 10 X tal A13596 No. 6655-18/54 R L 10F 10F 0.022F 100k 5V FMIF AM GND 240k 22k 100k 22k 1.5k 100k 5.6V 1k 9.1V R ON FM/AM VSM 240k 100F 100F 10k 0.015F 16 MPX OUT 0.015F LEFT CH. MUTE ADC 51k NC MPX GND 13 0.01F 12 LPF 11 68pF 10.26MHz 12 9 51k HPF 10 0.47F 9 1M 0.01F 8 10k 100pF 30k 0.022F 100pF 200k 10pF 0.22F 100pF 17 VDD 0.22F + + + + Block Diagram FMIF AM NC MPX VCC 22k GND 10F 10F + + 1k 50k AM LEVEL ADJ 1F 8200pF AM HC 10k 0.22F 100k 1F + 1F + FM METER NC-IN HCC SNC GND DET OUT AM/FM S-METER 0.47F 1F CSB912JF108 32 10k RIGHT CH. 31 30 29 28 27 26 25 24 23 22 21 20 0.047F 20k 19 SEP.ADJ 18 17 MUTE DRIVE TRIG + 33 P-CAN PHASE COMP VCO SUB MAT DEC RIX 15 14 FF FF 19k<0 FF 19k<90k FF 38k<0 1k RDS 2.2k 11 FM/AM 10 4.7k 100pF N.C.MPX GND 0.01F PI.CAN ADJ 1F 5.6k + 100k 0.47F PILOT DET + 0.47F AFC IN 34 MUTE AMP 10k QD IN 10k SNC HCC MAIN HC 0.1F VCO STOP INPUT FM SD ADJ. 30k KEYED AGC 6.8k AM OSC 39 0.22F 13 100pF 300pF 14 AMP 38 HOLE DET 6800pF VREF + - 37 Q.DET DC-C AFC DET CLAMP 36 MRC QD OUT MUTE DRIVE 35 40 GATE VCC GND IF AM/FM REG SW + 240k AMVSM AM SD NOISE 0.022F SEEK SW SD/ST IND AMP AGC 6 5 BUFF AM 1ST OSC AM/FM OSC BUFF 25pF 20pF 10F 4 18pF 30k 3 2k + TRIG AM LC 1k 42 IF BUFF COUNTER 2200pF 7 15 AM IN IF limiter amplifier AMP PICAN INPUT CHCC 41 FMVSM FM SD 100F + LA1787M + KEYED AGC 2.2F 5pF OSC BUFF IF AGC 44 AM FM VREF TWEET PILOT DET 0.022F 0.022F 43 1F DET L.C. RF AGC WB AGC 45 W.B.AGC RF AGC BUFF OSC OSC BUFF IF7 ANT D 46 FE GND 2 MIX 1 ANT D GND 1F 18pF RF AGC + 47 MIX 11k ANT D 10k RFAGC AM/FM 3.3F 57 5pF 5pF 58 59 60 61 62 63 64 + 48 54 55 2.7k 62pF FEVCC 0.022F MUTE ATT 220 100 AM IF IN FE IF IN 15pF FM IF IN 2.2k 22pF 8pF 330 30k 200k 18pF FM GND 100 0.022F 100k 30 1000pF 10k 3SK583 10k FM IF OUT AM SD ADJ AM MIX OUT FM WB AGCIN 20k 0.022F VCC 30 1000pF 0.022F 3SK263 180 0.01F 100k 0.1F 100k 100H 510k 15pF 15pF 100F 100k VCC 1000pF 9pF 100k 0.022F 39pF 0.022F 1MH + GND 47F 30k FM/AM VT 1k FC18 30 ANTD 0.022F 100k FM ANT IN 100k AM RF GND 1000pF 22pF 22pF 100H 0.022F 30MH 0.022F 22pF AM ANT IN AM VCC + 1F 49 50 51 52 53 56 + + TO AM STEREO (IF OUT) 22k 22k SEEKAM/FM SD STOPFM ST IND. +B 12V 22k + + + + SD/MONO ST LC867148 8 7 6 LC7216M 16 FM IN DO 5 DO CL 4 CL 18 PD CI 3 CI 19 VSS CE 2 CE 20 1 7.2MHz No. 6655-19/54 A13597 VCC GND 8V VCC 0.022F IF OUT 10k VREF IF7 + + + 1F 6.8k KEYED AGC 22k FM SD ADJ. 3.3F 50 2.2F 15k + + + 2200pF AC3 SG3 CHCC QD IN 240k MRC-IN 47 1F + 50 IF IN B SW2 ( i ) MIX A QD OUT AFC IN 0.1F 10k 36 FM S-METER DET OUT + MUTE OR ADJ 180k 0.022F 0.1F 300 4.3k VD5 100F 0.22F VA2 SW3 PILOT DET AM LC 0.47F + RFAGC 48 46 45 44 43 42 41 40 39 38 37 35 34 MUTE DRIVE 33 VCC2 ANT D OSC OSC BUFF 32 AM LEVEL ADJ 8200pF AM HC B SW4 (T) A + 18pF 31 1F 30 NC-IN HCC SNC 1F 27 MIX 55 TWEET 26 100k GND 25 24 23 FF 19<0 FF FM/AM REG SW -+ + + 49 FM IF IN 50 330 IF limiter amplifier 51 BUFF IF DET AGC 29 28 L.C. IF BUFF 54 + RF AGC W.B. AGC MRC DC-C AFC DET CIAMP AMVSM AM SD FMVSM FM SD HOLE DET MUTE DRIVE 52 53 Q.DET MUTE AMP AC5 200 AC Characteristics Test Circuit 30 0.022F AM IF IN NC-IN PG1 (AC1) HCC SNC 100k 100k 0.022F 1.6k 1mH FM IF OUT VCC3 100H FC18 FM WB AGCIN FE IF IN 56 57 10pF 58 W.B.AGC RF AGC KEYED AGC VCO STOP PILOT DET TRIG HPF HCC VCO 22 21 20 P-CAN FF 38k<0 MAIN HC AGC 64 5pF 1 OSC 20pF 5pF 25pF ANT D RF AGC FE GND 2 3 4 5 6 7 ANT D 8 9 14 15 16 MPX OUT 0.01F 10k 1M 0.47F TRIG GATE FF 19 18 SUB MA DEC TRIX 17 LPF MUTE ATT 59 60 FEVCC VCC AM/FM 62 3pF 63 5pF BUFF AM 1ST OSC 61 BUFF MIX AM FM VREF SNC AM SD ADJ AM MIX OUT VD4 VD2 50 30 100H + 20k 6.8mH AC2 SG2 330 FF 19<90 k PHASE COMP 0.022F 100k 47F 15pF 65pF + AM/FM S-METER 0.47F + SEEKAM/FM SD STOPAM ST BUFFER FM ST IND. 50k JIS DUMMY 510 0.022F LA1787M VA3 5.6k + + ANTD 0.022F FM/AM IFBUFF. 50k 0.22F 1F CSB912JF108 SW5 SW6 VD3 0.047F 20k 3pF 1M 10k 100k VR2 0.01F PI.CAN ADJ VCC2 VA8 5V VCC1 VD6 30k SW8 200k SW7 50 25 30 VR1 SEP. ADJ SW9 20k 8V 0.022F + AC1 SG1 50 VD1 100k 39pF 1000F 100 1F 0.022F 30k + N.C.MPX GND 300pF 20pF 100 0.022F GND 20k 3pF 0.022F 8V 0.022F 1M 10k SW10 10.26MHz X TAL VCC 0.022F SW1 10F + VCC 10F + FM GND FM VCC LEFT CH. 0.015F VT 8V AM/FM OSC BUFF 10k 10k VA6 VA1 VA9 VA7 A13598 RIGHT CH. 0.015F 10 11 12 13 AM OSC + 6800pF 0.01F No. 6655-20/54 LA1787M Test Conditions Parameter Current drain Demodulation output Pin 31 demodulation output Channel balance Total harmonic distortion (FM) Signal-to-noise ratio: IF AM suppression ratio: IF Symbol ICCO-FM VO-FM VO-FM31 CB THD-FMmono S/N-FM IF AMR IF Att-1 Muting attenuation Att-2 Att-3 Separation Stereo on level Stereo off level Main total harmonic distortion Pilot cancellation SNC output attenuation HCC output attenuation 1 HCC output attenuation 2 Input limiting voltage Muting sensitivity SD sensitivity 1 SD sensitivity 2 IF counter buffer output Separation ST-ON ST-OFF THD-Main L PCAN AttSNC AttHCC-1 AttHCC-2 Vi-lim Vi-mute SD-sen1 FM SD-sen2 FM VIFBUFF-FM VSM FM-1 Signal meter output (FM) VSM FM-2 VSM FM-3 VSM FM-4 Muting bandwidth Mute drive output N-AGC on input W-AGC on input Conversion gain Oscillator buffer output Gate time 1 Noise sensitivity NC effect MRC output MRC operating level Practical sensitivity Detection output Pin 31 detection output AGC F.O.M. Signal-to-noise ratio Total harmonic distortion (AM) Signal meter output (AM) Oscillator buffer output Wide band AGC sensitivity BW-mute VMUTE-100 VNAGC VWAGC A.V VOSCBUFFFM GATE1 SN SN-NC VMRC MRC-ON S/N-30 VO-AM VO-AM31 VAGC-FOM S/N-AM THD-AM VSM AM-1 VSM AM-2 VOSCBUFF AM-1 W-AGCsen 1 W-AGCsen 2 SD-sen1 AM SD-sen2 AM VIFBUFF-AM Switch states SW1 ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON/OFF ON ON OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF SW2 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b a a a a -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- SW3 OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF ON ON ON ON OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF SW4 b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b b a a a b b b b b b b b b b b b b b b b SW5 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- OFF ON OFF -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- ON ON ON ON ON ON ON ON ON ON ON OFF OFF OFF SW6 ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON OFF OFF OFF ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON OFF OFF OFF SW7 OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF -- -- -- -- -- -- -- -- -- -- -- -- -- -- SW8 OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF OFF -- -- -- -- -- -- -- -- -- -- -- -- -- -- SW9 ON ON ON ON ON ON ON ON ON ON ON ON ON ON OFF/ON ON ON ON ON ON ON ON ON ON ON ON ON ON ON -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- SW10 -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- ON -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- SD sensitivity IF buffer output No. 6655-21/54 LA1787M Usage Notes 1. Notes on VCC and Ground Pin 40 Pin 25 Pin 14 Pin 61 * Pin 6 Pin 3 VCC for the FM IF, AM, NC, MPX, and MRC blocks Ground for the FM IF and AM blocks Ground for the NC, MPX, and MRC blocks VCC for the FM front end, AM first mixer, and first oscillator blocks VCC for the FM front end and AGC blocks, and the AM/FM switching pin Ground for the FM front end, first mixer, and first oscillator blocks *: When applying the VCC voltage to pin 6, that voltage must not exceed the pin 40 and pin 61 VCC voltages. (This condition must be checked carefully when first applying the pin 6 voltage.) 2. Notes on AM Coil Connection The VCC used for the first oscillator coil connected to pin 7 must be at the same potential as pin 61. Connect to the IFT connected with pin 45, and to the MIX coil connected with pin 54. VCC must be at the same potential as pin 40. 3. AM/FM Switching Pin 6 is also used as the FM front end and RF AGC VCC Pin 6 voltage 8 OPEN Mode FM AM Fig. 1 LA1787M Overview 1. Notes on the LA1781M, LA1784M, and LA1787M The LA1784M is a version of the LA1781M that uses an external oscillator circuit, and has the same characteristics as the LA1781M. The LA1787M is a version of the LA1784M that features improved characteristics. LA1781M LA1784M This product is a version of the LA1781M with the oscillator circuit removed. It supports the use of an external oscillator circuit. It has the same characteristics as the LA1781M. LA1787M The LA1787M features improved characteristics over the LA1781M and LA1784M. No. 6655-22/54 LA1787M 2. Modified circuits The following characteristics have been improved over those of the The LA1784M. * The AM adjacent channel interference characteristics (40 kHz) have been improved. * The AM S-meter curve slope has been increased. * The FM separation temperature characteristics have been improved. * The stereo indicator sensitivity has been improved. * The FM oscillator circuit has been omitted. (1) AM interference characteristics improvement The second signal interference and suppression have been improved for adjacent channels (40 kHz) by increasing the AM second mixer input dynamic range. (2) The AM S-meter curve slope has been increased. The slope of the AM S-Meter curve has been increased from that of the LA1781M and LA1784M. AM S-Meter Voltage 7 6 S-meter voltage -- V 5 4 L 7 A1 87 M LA1780M 3 2 LA 17 81 M 1 0 -20 0 20 40 60 80 100 120 140 Antenna input -- dB (3) FM separation temperature characteristics improvement The temperature characteristics have been improved, the amount of change in the separation due to drift when at power on has been stabilized. This makes it easier to adjust the separation. Change in Separation (LA1781M): First IF Input 60 Change in Separation (LA1787M): First IF Input 60 55 55 Change in separation -- dB 50 Change in separation -- dB 2 3 50 45 45 40 40 35 0 1 35 0 1 2 3 Time after power on -- minutes Time after power on -- minutes No. 6655-23/54 LA1787M (4) Stereo indicator sensitivity improvement The stereo indicator sensitivity (on/off) is equivalent to that of the LA1780M Stereo on level LA1781M/1784M LA1787M/1780M 4.1% 2.6% Stereo off level 3.1% 1.6% (Typical value) *: The pilot level such that the stereo indicator goes on or off for a 10.7 MHz unmodulated IF input. (5) FM oscillator circuit removed The internal FM oscillator circuit provided in the LA1781M has been removed. The FM oscillator level can be adjusted by constructing an external circuit block. *: However, this requires 4 more external parts than the LA1781M: 1 transistor and 3 resistors/capacitors. VCC IC internal VCC IC internal VCC 4 Vt Vt 4 A13600 A13601 LA1787M/1784M FM OSC 3. Gain distribution LA1780M/1781M FM OSC The table below shows the gain distribution of the LA1780M, LA1784M, and LA1787M. (These are measured values.) Compared to the LA1784M, the total gain is lower. 1st MIX (10.7) LA1780M LA1784M LA1787M First mixer First IF amplifier Second mixer Second IF amplifier 10 dB 7.5 dB 7.5 dB : No circuit changes from the LA1784M. : Equivalent to the LA1780M circuit. (The gain is lower than that in the LA1781M and LA1784M.) : The mixer circuit has been modified to improve adjacent channel suppression and interference. : Equivalent to the LA1780M circuit. 1st IF (10.7) 3.3 dB 13 dB 3.5 dB 2nd MIX (450) 3.2 dB 7 dB 8.6 dB 2nd IF (450) 69 dB 66 dB 67 dB No. 6655-24/54 LA1787M 4. Changes to applications Component values that change from LA1781M/LA1784M applications (Since the total AM gain has changed in the LA1787M) * AM SD adjustment resistor (pin 55): Because Vsm is higher. * AM level adjustment resistor (pin 31): Since the post-detection audio amplifier gain is higher than in the LA1781M and LA1784M, the output level is also higher. This resistor must be changed to match the set value. * AM mixer coil (pin 54), IFT coil (pin 45) damp resistor: Since the IF block gain is increased, the mixer (pin 54) and IFT (pin 45) coil damping must be adjusted. * Separation adjustment resistor (pin 19): Since an internal 4 k resistor has been added to the pin 19 input circuit to improve the separation temperature characteristics, the value of the external resistor must be reduced from that used with the LA1780M, LA1781M, and LA1784M. (See the following page.) Composite Sign DECODER 5k Composite Sign DECODER 5k Added 4 k resistor 19 19 30k 0.047F A13602 30k 0.047F A13603 LA1781M/1784M Functions LA1787M 1. Notes on the FM Front End Notes on interference rejection characteristics * Intermodulation characteristics The LA1787M applies two high-band AGC functions to prevent IM (the generation of intermodulation). These are the narrow AGC (pin 58: mixer input detection type) and the wide AGC (for the pin 55 input), and this results in the antenna frequency characteristics shown in figure 2. The levels at which the AGC functions turn on are determined by the capacitors attached at pins 55 and 58. f -- AGC Sensitivity When f = 0, 98.1 MHz 110 AGC sensitivity -- dB 100 90 The wide AGC sensitivity when pin 39 is 5 V. 80 70 60 The narrow AGC sensitivity when pin 39 is at ground. -5 -4 -3 -2 -1 0 1 2 3 4 5 50 f -- MHz Fig. 2 No. 6655-25/54 LA1787M * Notes on second-channel attenuation suppression Keyed AGC (3D AGC) is a technique for achieving good characteristics for both intermodulation and secondchannel attenuation at the same time. When the desired signal is faint or nonexistent, the high-band AGC level will be essentially 0, and as a result automatic tuning may malfunction and blocking oscillation may occur in the presence of strong interfering stations. Keyed AGC helps resolve these problems. This 3D AGC technique uses information that has the following three frequency characteristics and is a unique Sanyo-developed system for determining the high-band AGC level. RF and ANT circuit information: Mixer input AGC Mixer circuit information: Mixer output AGC CF selectivity information: S-meter output * 3D AGC Features Feature Only the narrow AGC sensitivity (operation at f < 1.5 MHz) is controlled by the field strength of the desired station. The narrow AGC sensitivity is controlled by a voltage (V 23) that is under 0.5 V. Merit * Effective in resolving second-channel attenuation problems. * Allows effective resolution of second-channel attenuation problems without degrading three-signal characteristics. * Seek operations may stop incorrectly due to the occurrence of intermodulation. * It is possible to prevent the occurrence of intermodulation in the RF tuning circuit and antenna in the presence of strong interfering stations, and blocking oscillation due to AGC operation can be prevented. * Settings can be optimized for the field conditions. * Since the narrow AGC operates for the desired station and adjacent stations, the wide AGC sensitivity can be lowered and AGC malfunction due to local oscillator signal can be prevented. The wide AGC can operate even when V23 = 0 (when the desired station is not present). The narrow and wide AGC sensitivities can be set independently. (See figure 3 and 4.) The system has two AGC systems: narrow and wide AGC. (See figure 5.) f -- AGC on Level (ANT input) 110 Fig.3 f -- AGC on Level (ANT input) Fig.4 Pin 55 capacitor: 3 pF 110 Narrow AGC on level -- dB Wide AGC on level -- dB 100 100 90 90 80 Pin 58 capacitor: 10 pF keyed AGC 39 Pin 58 capacitor: 47 pF -5 -4 -3 -2 -1 0 1 2 3 4 5 Pin 55 capacitor: 10 pF 80 70 70 keyed AGC 39 5V -5 -4 -3 -2 -1 0 1 2 3 4 5 60 60 50 50 f -- MHz f -- MHz Fig.5 Pin 59 narrow AGC and pin 55 wide AGC input levels -- dB W-AGC, N-AGC -- f 70 80 Wide AGC on level frequency characteristic 90 s Narrow AGC on level frequency characteristics 100 110 120 130 140 7 1.0 AGC input level frequency characteristics such that VRFAGC (pin 2) falls under 2 V. 2 3 5 7 10 2 3 5 7 100 2 3 5 Frequency, f -- MHz No. 6655-26/54 LA1787M 3D AGC Sensitivity Characteristics AGC sensitivity Wide AGC sensitivity F 1 2 Second-channel attenuation improvement 3 Desired station AGC sensitivity Narrow AGC sensitivity 4 V23 (Desired station field strength) A12075 Fig. 6 3D AGC Sensitivity -- f, V23 characteristics * The wide AGC sensitivity is determined by the antenna and RF circuit selectivity, regardless of V23. * The narrow AGC sensitivity is determined by the following. The total selectivity of the antenna, RF circuit, and mixer when V23 0.5 V The above selectivity and V23 when V23 < 0.5 V * The improvement in the second-channel attenuation corresponds to the area occupied by the narrow AGC in the total AGC sensitivity area. Figure 8 on the next page shows the actual operation of the circuit. f -- AGC on Level (ANT input) The fu input level at which antenna damping turns on -- dB 110 fD = 98.1 MHz Second-channel pad 100 90 80 ANT IN VIN 70 60 fu = 98.1 MHz + f A12076 50 -5 -4 -3 -2 -1 0 1 2 3 4 5 f -- MHz Fig. 7 No. 6655-27/54 LA1787M Notes on 3D AGC (Keyed AGC) VCC 55 W-AGC DET 58 N-AGC DET 90A S-meter + - VCC + - 1 2 + 39 24 ANT DUMPING VS-meter A11763 Fig. 8 * The antenna damping current from the pin due to the pin diode flows when the V2 pin reaches the VCC - VBE level. * The narrow AGC operates as follows. When pin V39 > pin V24: The narrow AGC turns off. When pin V39 < pin V24: The narrow AGC turns on. No. 6655-28/54 LA1787M * The LA1787M includes two AGC circuits in its front end block. -- Antenna input limiter using a pin diode. -- FET second gate control The AGC input pin is pin 59, and the AGC circuit turns on when a signal of about 30 mVrms is input. AGC activation The pin diode drive circuit turns on when VCC - V2 is greater than or equal to about 1 V, and input limitation is applied to the antenna circuit. In application circuits, there will be an attenuation of about 30 to 40 dB. Next, when an adequate current flows in the antenna attenuator pin diode, the inductance falls, the FET second gate voltage drops, the FET gm falls, and the AGC operates. The recommended FET is the Sanyo 3SK263, which is an enhancement-type MOSFET. Therefore, full AGC is applied when the voltage, VG2-S, between the second gate and the source is 0. Note that if a depletion-type MOSFET is used, AGC will not be applied unless VG2-S is less than 0. V2 AGC Characteristics 9 8 7 Fig.9 fr = 98.0 Hz VCC = 8 V Ta = 25C V2AGC -- V 6 5 4 3 2 1 0 -10 Range where AGC level AGC level due the AGC does due to the to the MOSFET not operate pin diode: second gate: about 35 dB about 35 dB 0 10 20 30 40 50 60 70 80 90 100 110 120 130 140 ANT IN -- dB MIX INPUT MIX OUT MIX OUT MIX INPUT Due to optimized device geometry, emitter current, the bias, this IC achieves the following performance. Mixer input usable sensitivity: 15 dB Mixer input IMQS: 90.5 dB (For an oscillator level of 200 mVrms) OSC MIX * The mixer input IMQS is defined as: fr = 98.8 MHz, no input fu1 = 98.8 MHz, 1 kHz, 30% modulation fu2 = 99.6 MHz, no modulation The interference 1 and 2 input levels such that generated intermodulation output signal-to-noise ratio becomes 30 dB when an interference signal with the same level as the mixer input is input, and distortion occurs in the mixer. Mixer circuit Fig. 10 A12077 No. 6655-29/54 MIX VCC * Mixer The mixer circuit in this IC is a double-balanced mixer with both balanced input and balanced output. Input circuit type Emitter input Input impedance: 25 64 59 60 63 62 LA1787M * Oscillator Figure 11 shows the type of oscillator circuit used in this IC. It includes both an oscillator and an oscillator buffer. VCC 18pF 4 25pF 5 VT 20pF AM/FM OSC BUFFER OUT A12078 Fig. 11 * Figure 12 shows the type of FM first IF amplifier used in this IC. It is a differential single-stage amplifier. 330 TO MIX FM IF input 56 53 330 + 330 - A12079 Fig. 12 Specifications Input impedance: 330 Output impedance: 330 Gain: 20 dB No. 6655-30/54 LA1787M 2. FM IF * Notes on the FM SD and SD adjustment The figure below presents an overview of the FM SD and the IF count buffer. 4.9V R R + - + - Band muting HOLE CLET Muting drive output R STEREO IND S-meter + - IF count buffer FM IF 33 23 26 5V IF count output SD STEREO/MONO 2.5V 5V 39 24 Fig. 13 A11759 Figure 14 shows the relationship between the FM SD, the IF count buffer output, the S-meter, and the muting drive output. V24 V38 V33 Smaller values of R33 Larger values of R33 S-meter V33 over 0.7 V V26 5V On as an SD signal V23AC SD ON V33 over 0.7 V SD ON Mono Stereo 0.7 V OFF V23DC IF count buffer 5V OFF IF counter output off 2.5 V 0V RDS and other types of SD detection can be used by switching these modes. New LA1784M functionality: For stereo input (when the V26 pin voltage is 0.7 V), when this pin is shorted to ground (0.1 V or lower) the IC will operate in forced mono mode. A11758 Fig. 14 No. 6655-31/54 LA1787M * Transient response characteristics during automatic tuning The transient characteristics for SD and IF count buffer on/off operation are determined by the time constants of the RC circuits attached to the following pins. (1) Muting time constant: pin 33 (2) S-meter time constant: pin 24 (3) AFC time constant: pin 34 There are two points that require consideration when using fast tuning. (1) The SD time constant due to the S-meter time constant Since the current I24 (pin 24) varies with the field strength, the time constant also changes. There is no hysteresis in the comparator. If a smaller value is used for C24, you must select a value for C such that the AGC does not become unstable when the pin 24 voltage is used for keyed AGC. S-meter 10k 24 C24 A12080 Fig. 15 (2) The SD time constant due to the pin 33 muting voltage time constant The changes in volume due to field fluctuation during weak field reception can be made smoother by setting the attack and release times during soft muting operation. Mute drive 10k Attack 33 C33 50k Release Mute amp Muting time constants Attack: 10 k x C33 Release: 50 k x C33 A11766 Fig. 16 SD Sensitivity Adjustment Antenna input such that pin 5 goes high -- dB 50 Fig.17 40 30 20 10 0 6 10 14 18 22 26 30 34 Resistance between the pin and ground -- k No. 6655-32/54 LA1787M However, when testing this stop sensitivity, note that when checking the waveform on the IF count buffer output (pin 23), there are cases, such as that shown below, where current in the test system may be seen as flowing to ground and cause oscillation that causes the IF count buffer output to go to the output state. F.E. IF IF buffer amp 5V 0.022 F Test system capacitance The 10.7 MHz feeds back through ground. Fig. 18 A12081 * FM Muting control pin (pin 47) (R47: 30 k variable resistor) The -3 dB limiting sensitivity can be adjusted with R47. FM Soft Muting (1) R47 = 7.5 k 15 k Fig.19 DET out Output, noise -- dB Output 10 k 20 k Noise Antenna input -- dB * FM muting attenuation adjustment (pin 58) The muting attenuation can be switched between the three levels of -20, -30, and -40 dB by the resistor inserted between pin 58 and ground. (Note that the exact values depend on the total tuner gain.) The noise convergence with no input is determined by the pin 58 voltage. 58 R58 Open Mute ATT -20 dB -30 dB -40 dB 100 R58 200 k 30 k A11764 The attenuation can be set by making R33 smaller as listed in the table above. 33 R33 A11765 Fig. 20 No. 6655-33/54 LA1787M FM Soft Muting (2) R47 = 7.5 k Fig.21 DET out FM Soft Muting (3) R47 = 7.5 k Fig.22 DET out 10 k Output, noise -- dB Output noise -- dB Output -- dB 10 k 15 k Output -- dB 15 k 200 k 30 k 20 k Noi se 2 0k Nois e Antenna input -- dB VCC Quadrature detector 200 k R + - Antenna input -- dB Mute amp. (VCA) R + N-AGC - Mute drive R Limiter 58 33 31 DET out To MIX out Open 200 k 30 k Fig. 23 A11767 * FM muting off function Forcing this pin to the ground level turns muting off. Detector output 0 1 When the pin is at the ground level, the noise convergence will be 10 dB and the -3 dB limiting sensitivity will be about 0 dB. 20 Antenna input A12082 Fig. 24 No. 6655-34/54 LA1787M * Hall detection The Hall detection function detects the level of the pin 36 quadrature input signal and then applies peak detection to that result. The result is output from pin 33. This circuit has three effects. (1) It assures that muting will be applied for weak inputs with an antenna input of under 5 dB. The amount of attenuation is referenced to an antenna input of 60 dB, fm = 1 kHz, and a 22.5 kHz dev output, and is variable from 10 dB to 40 dB when there is no input. Thus one feature of this circuit is that the weak input noise attenuation and the -3 dB limiting sensitivity for over 5 dB inputs can be set independently. Hall Detection Output -- Antenna Input Characteristics Fig.25 5 Area muted by Hall detection 4 V38pin -- V 3 2 1 0 -20 -10 0 10 20 30 Antenna input -- dB (2) When the pin 36 quadrature input is a saturated input, the pin 36 noise level (Va) is detected and a peak-hold function is applied to pin 33 (Vb) for locations rapid field strength variations and severe multipath occurs for fields that result in an antenna input level of over 5 dB. 36 33 Vb + Va 0.1F 0 0 A12083 Fig. 26 (3) Unique features One unique feature of the LA1784M is that if there are adjacent stations such that f1 = 98.1 MHz and f2 = 97.9 MHz, a search operation will not stop at 98.0 MHz. Since VAFC = 0 V and VSM = 3.6 V at 98.0 MHz in the situations shown in figure 27 and 28, even though Hall detection would normally not operate and SD would be high, in this IC the Hall detection circuit will operate, VMute will be set to 1.2 V (over 0.7 V) and the SD signal will go low, thus preventing incorrect stopping of the search. No. 6655-35/54 LA1787M Voltage between pins 37 and 34, VAFC -- V Pin 33, VMute -- V Voltage between pins 37 and 34, VAFC -- V Pin 33, VMute -- V Unique Features of the LA1784M Hall Detection Circuit (1) 2 1 Fig.27 ANT IN Unique Features of the LA1784M Hall Detection Circuit (2) 2 1 Fig.28 When the tuner is moved in 50 kHz steps. With a 51 k resistor between pins 37 and 34. With the SD sensitivity adjusted to be 20 dB. f1 f2 When the tuner is moved in 50 kHz steps. With a 51 k resistor between pins 37 and 34. With the SD sensitivity adjusted to be 20 dB. 0 0 -1 -1 6 6 4 4 2 2 0 0 Pin 24, VSM -- V 4 Pin 24, VSM -- V 6 6 4 2 2 0 8 Pin 26 (SD) -- V 6 Pin 26 (SD) -- V f2 = 97.9 MHz, 120 dB fm = 400 Hz, 22.5 kHz dev. f1 = 98.1 MHz, 120 dB fm = 1 kHz, 22. 5kHz dev. 0 8 6 f2 = 97.9 MHz, 40 dB fm = 400 Hz, 22.5 kHz dev. f1 = 98.1 MHz, 40 dB fm = 1 kHz, 22.5 kHz dev. 4 4 2 0 97.7 2 0 97.7 97.8 97.9 98.0 98.1 98.2 98.3 97.8 97.9 98.0 98.1 98.2 98.3 Frequency, fr -- MHz Frequency, fr -- MHz * Notes on the quadrature input level When a strong field is being received the quadrature signal input (pin 36) requires a 200 mV rms input, and the detection transformer and the damping resistor between pins 36 and 37 must be designed. (We recommend the Sumida SA-208 transformer and a 10 k resistor between pins 36 and 37.) When the pin 36 input level falls below 160 mV rms, the Hall detection circuit operates and the pin 33 mute drive output voltage increases. Therefore, when pin 36 input is from 160 to under 200 mV rms during strong field reception, the muting circuit may or may not operate due to sample-to-sample variations between individual ICs. Furthermore, the SD function may not operate, and the audio output level may be reduced. Incorrect operation due to sample-to-sample variations and temperature characteristics can be prevented by keeping the pin 36 voltage at 200 mVrms or higher. Pin 33 VMute -- QD Input Level 6 Fig.29 SA208 + LA1787M IF Input Characteristics 4 0.8 3 0.6 2 0.4 Fig.30 With pins 34 and 37 shorted. With 5 V applied to pin 24. 5 Vmute -- V THD -- % 4 1 0.2 -100 -80 -60 -40 -20 -120 0 -0.2 -0.4 20 40 THD 1 kHz 75 kHz dev f -- kHz 60 80 100 120 3 2 SG 1 75 0.022 F 75 + With the resistor between pins 36 and 37 open. With a 10 k resistor between pins 36 and 37. f=0 10.7 MHz 10.7 MHz 0 92 94 96 36 98 37 LA1888M 100 102 104 106 -0.6 Voltage between pins 37 and 34 -0.8 (referenced to the pin 37 voltage) QD input level -- dB No. 6655-36/54 LA1787M Detector output Pin 36 AC level MPX OUT Vo QDIN 330 mVrms 280 mVrms 235 mVrms 200 mVrms R36-37 Open 10 k * Band Muting Adjustment Procedure The muting bandwidth can be modified as shown in figure 31 with the resistor RBW between pin 34 and 37. RBW -- Muting Bandwidth Bandwidth such that the pin 33 voltage 2 V -- kHz 280 RBW 240 + + Fig.31 1 F 0.47 F 200 10 k 160 37 36 35 SA208 Sumida 34 ANT IN 98 MHz 100 dB 120 80 40 0 1.0 2 3 5 7 10 2 3 5 7 100 2 Resistor RBW between pins 34 and 37 -- k 3. AM * AM AGC system The LA1787M RF AGC circuit takes its input from three sources: the WIDE AGC pin (pin 46), the MIDDLE AGC pin (pin 49) and NARROW AGC. There is also an IF AGC circuit. RW 1st MIX 10.7MHz CF RF 62 49 2nd MIX 450kHz CF 52 IF Amp. DET 31 VCC 42 1st OSC X'tal 240 k VCC 46 Middle AGC IN Narrow AGC IN Wide AGC IN ANT damping 57 + 47 F RF AGC Amp. IF AGC 44 2.2 F 48 + 3.3 F Fig. 32 A11762 No. 6655-37/54 LA1787M AM AGC f characteristics Wide AGC Operates for wide band interference 100 Fig.33 90 Wide AGC Operates for wide band interference 80 AGC on level Middle AGC Operates for interference within 70 kHz of the received frequency. Middle AGC Operates for interference within 70 kHz of the received frequency. 70 Narrow AGC Operates at the received frequency. 800 900 60 1000 1100 1200 Frequency -- Hz Wide Band AGC Circuit 120 Fig.34 Antenna damping on input level -- dB 30 110 -6dB SG 100 ANTD 0.022 F 90 0.022 F 50 50 46 0.022 F Received frequency: 1 MHz 510 80 70 1.0 2 3 5 7 10 2 3 5 Pin 46 input -- MHz The wide band AGC circuit in this IC has the frequency characteristics shown above. The pin 46 input frequency characteristics are identical to those of the RF amplifier gate. This AGC circuit serves to prevent distortion at the FET input when a strong signal is applied to the antenna circuit. The level at which the AGC circuit turns on can be adjusted to an arbitrary level with the wide band AGC adjustment resistor. A delayed AGC on level can be handled by reducing the value of the adjustment resistor. Wide band AGC adjustment resistor 0.022 F VCC 30 620 1MH 100 H FC18 57 47 F 15 pF 15 pF + 100 H 0.022 F 100 k 30MH 62 Fig. 35 A12084 No. 6655-38/54 LA1787M * Notes on AM SD (pin 26) and the SD adjustment pin SD and the IF buffer are operated by comparing the S-meter level (V24) and the 5 V reference voltage as shown in figure 36. S-meter VCC Comparator + - AM IF IF buff amp. 50 pF 50 A 55 100 k 24 0.47 F 23 26 100 k 51 k 0.022 F 5V IF buffer Seek 5V Fig. 36 SD A12085 Figure 37 shows the relationship between the AM SD, the IF count buffer, and the S-meter. V24PIN V55 V26 Smaller values of R55 Larger values of R55 S-meter SD on V23AC OFF V23DC 5V Pin 55: AM SD adjustment pin 0V A11760 IF buffer on Fig. 37 No. 6655-39/54 LA1787M * AM high band cut and detector output level adjustment methods The pin 31 AM and FM tuner output has an impedance of 10 k in AM mode and a few tens of Ohms in FM mode. Therefore, R31 is used to lower the AM detector output level and C31 determines the AM high band frequency characteristics. VCC FM detector 31 R31 C31 VCC AM detector 10 k + Noise canceler input 30 50 k A12086 Fig. 39 * AM stereo system pins To the AM stereo decoder VCC IFT 45 39 GND 400 mV rms 450 kHz output VCC 50 pF 150 Keyed AGC IF AMP. Fig. 40 A11761 No. 6655-40/54 LA1787M * AM low band cut adjustment method The AM low band frequency characteristics can be adjusted with C42, which is inserted between pin 42 and VCC. Since the detector is designed with VCC as the reference, C42 must be connected to VCC. Detector Output -- Frequency 10 Fig.42 VCC C42 42 50 k AM detector 50 k 10 k A12087 0.022 F (41pin) With no used (31pin) 0 Detector output -- dB -10 0.022 F (41pin) With no used (31pin) 0.043 F (41pin) % with no used (31pin) 10 k + - 10 k To pin 31 -20 0.022 F (41pin) 8200 pF (31pin) -30 Fig. 41 -40 0.001 2 3 fr = 1000 kHz fm = 1 kHz, 30% 5 70.01 2 3 5 7 0.1 23 5 7 1.0 23 5 7 10 Frequency -- Hz 4. Noise Canceler Block * The noise canceler input (pin 30) has an input impedance of about 50 k. Check the low band frequency characteristics carefully when determining the value of the coupling capacitor used. Note that fC will be about 3 Hz when a 1 F capacitor is used in the application. * Pins 8 and 9 are used to set the noise detector sensitivity and the noise AGC. It is advisable to first set the noise sensitivity for a medium field (an antenna input of about 50 dB) with pin 8 (the noise sensitivity setting pin), and then set the AGC level for a weak field (20 to 30 dB) with pin 9 (the AGC adjustment pin). If the noise sensitivity is increased, the AGC will become more effective but, inversely, the weak field sensitivity will be reduced. Noise canceler 10 kHz overmodulation malfunction may be a problem. In particular, when an overmodulated signal is input, the noise canceler may, in rare cases, malfunction. This is due to the fact that the IF detector output has a waveform of the type shown in figure 43 due to the bands of the IF ceramic filters as shown below. (Here, the antenna input is 60 dB, the ceramic filters are 150 kHz x 1 and 180 kHz x 2, f = 10 kHz, 180 kHz dev.) The noise canceler reacts to the spikes (whiskers) generated due to this overmodulation, which results in distortion to the audio output. (The spike components due to overmodulation occur due to the bands of the ceramic filters in the tuner.) The following describes a method for resolving this problem. This incorrect operation due to overmodulation is prevented by removing the spike components due to this overmodulation with a low-pass filter consisting of a 1 k resistor and a 2200 pF capacitor shown in figure 44. However, note that the FM separation characteristics in the high band and the AM frequency characteristics will change. H1 W1 2.5OU IF audio output f = 10 kHz,180 kHz dev IF output 31 + 1 k Noise canceler input - 30 2200 pF 1 F A12089 Fig. 44 -2.5OU -19.00 s Fig. 43 981.00 s A12088 No. 6655-41/54 LA1787M 5. Multiplexer Block * HCC (high cut control) frequency characteristics (pin 41) When the HCC function operates, the frequency characteristics of the output signal are determined by the capacitance of the external capacitor connected to pin 41. 20 k To the matrix 41 C VO (dB) Fig. 45 A12090 1 fC = -------------- [Hz] 2 x C x 20 k Frequency Characteristics 10 0 1 2C x 20 k Fig. 46 f (Hz) A12091 Fig.47 Changes in the pin 41 capacitor capacitance (for a 100% high cut ratio) 0.001 F 0 F Attenuation, HCC -- dB -10 0.0022 F -20 0.0047 F 0.0 -30 F 1 -40 -50 -60 3 VCC = 8.0 V f = 98 MHz 100%mod 80 dB IN 5 7 100 2 3 5 7 1k 2 3 5 7 10k 2 3 Frequency, f -- Hz * Pilot canceler adjustment (pins 17 and 18) Noise 30 canceler input - To the multiplexer Fig. 48 Gate Pilot cancel 11 12 17 18 6800 pF 3.9 k 0.01 F 50 k A12092 The pilot canceler signal waveform (pin 19) is a 19 kHz signal that contains no third harmonic as shown in figure 48. Since this signal has the same phase as the pilot signal, no capacitor is required between pin 18 and ground. Since it has no third harmonic component, excellent pilot cancellation can be acquired in both the left and right channels by adjusting with a variable resistor. No. 6655-42/54 LA1787M * Separation adjustment (pin 19) 5 k 19 A12094 To the subdecoder Larger 20 k 0.047 F C Fig. 49 A12093 The separation is adjusted by modifying the input level to the subdecoder with the variable resistor connected to pin 19. Since only the sub-modulation level is changed by changing the variable resistor setting, the monaural (main) output level is not changed. Furthermore, degradation of high band separation in the decoder can be avoided if the impedance of the external capacitor (C) in the subchannel frequency band (23 to 53 kHz) is made sufficiently smaller than the variable resistor. 6. MRC Circuit VCC 2 A 100 DC buffer MRC 6.4 k 3.6 k 24 + S-meter FM S-meter QMRC 30 k 10 k 75 pF 1 k 32 Noise amplifier High-pass filter with Fc = 70 kHz + amplifier 27 + C27 VCC An external transistor equivalent to the 2SC536 is required Reason: A QMRC level shifter is required to allow a simplified MRC circuit to be used in the LA1787M. To the SNC, pin 28 A11768 Fig. 50 No. 6655-43/54 LA1787M (1) When there is no AC noise on pin 32 V24 = V27-VBE QMRC V27 is about 2.5 V when the antenna input is 60 dB or higher. (2) Since the MRC noise amplifier gain is fixed, the MRC circuit is adjusted by reducing the AC input level. 32 + Fig. 51 A11769 (3) The MRC attack and release are determined by C27 on pin 27. Attack: 7 A * C27 2 A * C27 Release: 500 * C27 100 Notes on the Noise Canceler The noise canceler characteristics have been improved by implementing the circuit that determines the gate time in logic. Since the time constant in earlier noise cancelers was determined by an RC circuit such as that shown in figure 52, the rise time shown in figure 53 was influenced by the values of the resistor and capacitor used. As a result the noise exclusion efficiency was reduced by this delay in the rise time. In the LA1787M, this rise time was shortened by implementing the circuit that determines the gate time in logic, allowing it to reliably exclude noise. A11771 A11772 Fig. 52 Fig. 53 No. 6655-44/54 LA1787M Gain Distribution (FM) This section investigates the gain in each block in the LA1787M when the Sanyo recommended circuits are used. (Test conditions) Ambient temperature: 26C Antenna and mixer input frequency: 98.1 MHz First and second IF input frequency: 10.7 MHz The input levels when VSM = 2 V will be as follows. ANT IN: 19 dB MIX IN: 30 dB 1st IF IN: 42 dB 2nd IF IN: 60 dB When the gains for each block are determined according to the above, the results are as follows. RF GAIN: 11 dB MIX GAIN: 12 dB 1st IF GAIN: 18 dB FM MIX IN 64 pin 1st IF IN 56 pin RF ANT IN 2nd IF IN 51 pin 11 dB 12 dB Fig. 54 18 dB A11773 No. 6655-45/54 LA1787M (AM) This section investigates the gain in each block in the LA1787M when the Sanyo recommended circuits are used. (Test conditions) Ambient temperature: 26C Antenna and mixer input frequency: 1 MHz First and second mixer input frequency: 10.7 MHz Second IF input frequency: 450 kHz The gains at each stage will be as follows. RF Gain (ANT IN-pin62): 17 dB 1st MIX Gain (pin62-pin56): 8 dB 1st IF Gain (pin55-pin53): 15 dB AM 1st MIX RF 1st IF 2nd MIX 2nd IF AM DET RF Gain 1st MIX Gain 1st IF Gain Fig. 55 2nd MIX Gain 2nd IF Gain A11774 No. 6655-46/54 LA1787M Input Circuits for Each Stage [FM] * Mixer input 0.022 F 63 75 64 75 75 300 0.022 F 56 * First IF input 75 VIN Actual measurement fr = 10.7 MHz A11775 A11776 * IF input 75 300 0.022 F 51 330 50 0.022 F fr = 10.7 MHz A11777 75 [AM] * First mixer input 50 0.022 F 62 50 * Second mixer input 50 0.022 F 49 50 fr = RF A11778 fr = 10.71 MHz (f2nd osc + 0.45 MHz) A11779 * IF input 50 0.022 F 52 50 * Del input 50 0.022 F 45 50 IFT fr = 450 kHz A11780 fr = 450 kHz A11781 No. 6655-47/54 LA1787M Sample AM tuner Circuit with the LC72144 Used Together 2nd MIX RF 1st IF CF CF 450K CF IF 300 XBUFF LC72144 fosc A11782 AM 1st IF 1 2 fOSC 10.25 MHz fOSC 10.35 MHz 10.7 MHz 10.8 MHz Step 10 kHz, 11 kHz 9 kHz, 10 kHz FM IF 10.7 MHz 10.8 MHz RF 62 1st MIX 10.71 MHz CF 59 60 1st OSC 56 53 IF CF 49 54 CF 52 10 k AF 2nd OSC 31 10.26 MHz NC MPX Lch Rch 10.7 MHz RF 63 64 60 59 IF CF 56 53 CF 51 Quadrature detector AF A11783 No. 6655-48/54 LA1787M Crystal Oscillator Element Kinseki, Ltd. Frequency: 10.26 MHz CL: 20 pF Model No.: HC-49/U-S Coil Specifications Sumida Electronics, Ltd. [AM Block] AM FILTEER (SA-1051) 1 2 3 AM OSC (SA-359) S 3 2 4 6 4 1 6 AM IF1 (SA-264) 3 4 AM IF2 (SA-1063) 3 2 4 S2 1 6 1 6 S S S AM loading (SA-1062) 3 2 1 6 4 AM ANT IN (SA-1048) 3 2 1 6 4 S S AM RF amplifier (RC875-222J) 0.1o2UEW [FM Block] FM RF (SA-1060) S 3 2 1 6 4 3 2 1 6 4 FM ANT (SA-1061) S FM OSC (SA-1052) 3 2 1 6 4 FM MIX (SA-266) S 3 2 C1 4 8 7 1 C2 6 S S A136 FM DET (SA-208) S 3 2 1 6 S 4 No. 6655-49/54 LA1787M The Toko Electric Corporation [AM Block] AM FILTEER (A2861BIS-15327) 1 2 3 AM OSC (V666SNS-214BY) 3 2 4 6 4 1 6 0.1o2UEW AM IF1 (7PSGTC-5001A) 3 2 1 6 0.05o3UEW 4 AM IF2 (7PSGTC-5002Y) 3 2 1 6 0.05o3UEW 4 AM loading (269ANS-0720Z) 3 2 1 6 0.05o3UEW 4 AM ANT IN (385BNS-027Z) S 3 2 1 6 4 AM RF amplifier (187LY-222) S 0.1o2UEW [FM Block] FM RF (V666SNS-208AQ) S3 2 1 4 FM ANT (V666SNS-209BS) 3 2 4 o0.1-2UEW 6S o0.1-2UEW 1 6S FM OSC (V666SNS-205APZ) 3 2 1 4 FM MIX (371DH-1108FYH) S3 2 4 5 o0.12-2UEW 6S o0.07-2UEW 1 6S FM DET (DM600DEAS-8407GLF) 3 2 1 6 0.07o2MUEW 4 No. 6655-50/54 LA1787M Coil Specifications Sagami Elec Co., Ltd. [AM Block] AM FILTEER (000021055) 1 2 3 AM OSC (000021056) S 3 2 4 5.1H 6 6 4 1 AM IF1 (000021057) 3 2 4 AM IF2 (000021059) 3 4 180pF 2 6S 1 6 180pF S1 S AM loading (000021061) 3 2 1 6 4 AM ANT IN (000021062) 3 4 30mH 2 1 6 100H S S AM RF amplifier (000021063) 2.2mH [FM Block] FM RF (000021064) S 3 2 1 6 4 3 2 1 6 4 FM ANT (000021065) 105.5nH S S FM OSC (000021066) 3 2 1 6 4 FM MIX (000021067) S 3 4 5 6 62.7nH 2 1 1-2 : 100pF 2-3 : 100pF S S FM DET (010021075) S3 2 1 6 4S 1-3 : 20H 3-4 : 120pF No. 6655-51/54 Mixer output -- dB Output, noise, AM output -- dB Total harmonic distortion, THD -- % Output, noise, AM output, LR output -- dB Input -- dB Antenna input -- dB Mixer input -- dB Antenna input -- dB DCV -- V Output, noise -- dB Antenna input -- dB Antenna input -- dB LA1787M First IF output -- dB HCC, SNC, RF AGC, muting voltage, S-meter voltage, VSM -- V Input -- dB First IF input -- dB No. 6655-52/54 LA1787M First IF output -- dB Frequency, -- MHz First IF output -- dB Frequency, -- MHz S/N, AM output -- dB AGC on, separation, input level -- dB Antenna input -- dB Ambient temperature, Ta -- C 20 Ambient temperature, Ta -- C AM I/O Characteristics VCC = 8.5 V f = 1 MHz mod = 1 k 30% OUT 0 Separation, Sep -- dB Output, noise -- dB -20 -40 NOISE -60 -80 -100 -20 0 20 40 60 80 100 120 140 Ambient temperature, Ta -- C ANT input, IN -- dB AM DC Characteristics 7.0 AM Distortion 7.0 RF AGC 6.0 Total harmonic distortion, THD -- % VCC = 8.5 V f = 1 MHz 6.0 VCC = 8.5 V f = 1 MHz mod = 1 k 30% 80% AGC, S-meter voltage -- V 5.0 5.0 4.0 4.0 3.0 3.0 2.0 VS M 2.0 1.0 1.0 0 -20 0 20 40 60 80 100 120 140 0 -20 fm = 1 kH 0 20 40 fm = 1 kH 60 IF AGC z 80% z 30% 80 100 120 140 ANT input, IN -- dB ANT input, IN -- dB No. 6655-53/54 LA1787M 20 AM Second-Channel Interference Rejection Characteristics 100 dB 40 kHz 20 AM Second-Channel Interference Rejection Characteristics 400kHz desire mod ON 40 d 0 desire mod ON 40 dB 0 100 dB B Output, noise -- dB Output, noise -- dB 60 dB 80 dB 60 dB 80 dB -20 -20 -40 40 dB desire mod 60 dB OFF fD=1MHz fm=1kHz 30% dB 80 80 dB 100 dB 50/3 15pF ANT IN 50/3 -40 desire mod OFF 60 dB 50/3 50 50/3 15pF ANT IN -60 50 -80 40 60 80 30 50 50/3 VIN 65pF fu=1040kHz fm=400Hz 30% JIS ANT. DUMMY 100 120 140 -60 fD = 1 MHz fm = 1 kHz 30% -80 40 60 80 30 50 50/3 VIN 65pF fu = 1400 kHz fm = 400 Hz 30% JIS ANT. DUMMY 100 120 140 ANT input, IN -- dB ANT input, IN -- dB Specifications of any and all SANYO products described or contained herein stipulate the performance, characteristics, and functions of the described products in the independent state, and are not guarantees of the performance, characteristics, and functions of the described products as mounted in the customer's products or equipment. To verify symptoms and states that cannot be evaluated in an independent device, the customer should always evaluate and test devices mounted in the customer's products or equipment. SANYO Electric Co., Ltd. strives to supply high-quality high-reliability products. However, any and all semiconductor products fail with some probability. It is possible that these probabilistic failures could give rise to accidents or events that could endanger human lives, that could give rise to smoke or fire, or that could cause damage to other property. When designing equipment, adopt safety measures so that these kinds of accidents or events cannot occur. Such measures include but are not limited to protective circuits and error prevention circuits for safe design, redundant design, and structural design. In the event that any or all SANYO products (including technical data, services) described or contained herein are controlled under any of applicable local export control laws and regulations, such products must not be exported without obtaining the export license from the authorities concerned in accordance with the above law. No part of this publication may be reproduced or transmitted in any form or by any means, electronic or mechanical, including photocopying and recording, or any information storage or retrieval system, or otherwise, without the prior written permission of SANYO Electric Co., Ltd. Any and all information described or contained herein are subject to change without notice due to product/technology improvement, etc. When designing equipment, refer to the "Delivery Specification" for the SANYO product that you intend to use. Information (including circuit diagrams and circuit parameters) herein is for example only; it is not guaranteed for volume production. SANYO believes information herein is accurate and reliable, but no guarantees are made or implied regarding its use or any infringements of intellectual property rights or other rights of third parties. This catalog provides information as of July, 2002. Specifications and information herein are subject to change without notice. PS No. 6655-54/54 10 0d B 40 dB |
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