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1892

1892

  • 厂商:

    NEC(日电电子)

  • 封装:

  • 描述:

    1892 - MATRIX SURROUND SOUND PROCESSOR WITH SOUND PROCESSOR - NEC

  • 数据手册
  • 价格&库存
1892 数据手册
DATA SHEET Bipolar Analog Integrated Circuit µPC1892 MATRIX SURROUND SOUND PROCESSOR WITH SOUND PROCESSOR The µPC1892 is a specific IC to reproduce surround sound by using phase shifters and a signal matrix. The µPC1892 provides wide sound with two speakers, and rich stereophonic sound with three speakers. In case of stereo signal, the µPC1892 has the movie mode to reproduce sense of immediacy (for movie) and the music mode to emphasize vocal sound (for music), and it has the simulated mode to make monaural signal into wide deep sound. The modes can be selected freely by using 2-bit parallel control pins. In addition to this function reproducing surround sound, the µPC1892 has a general sound processor that has volume, balance, bass and treble control. So it is capable of reducing installation area. All functions for processing signals of base band sound are provided on one chip. FEATURES • • • • • Three surround modes are available: movie, music and simulated Built in volume and balance control (All control voltage: 0 V to 5 V) Built in tone control (bass, treble) (All control voltage: 0 V to 5 V) Built in L+R output for woofer SP µPC1892CT-02: The volume and balance attenuation are bigger than µPC1892CT. APPLICATION • TV ORDERING INFORMATION Part Number Package 30-pin plastic shrink DIP (400 mil) 30-pin plastic shrink DIP (400 mil) µPC1892CT µPC1892CT-02 The information in this document is subject to change without notice. Document No. S10650EJ3V0DS00 (3rd edition) (Previous No. ID-2902) Date Published October 1995 P Printed in Japan © 1991, 1992, 1995 µPC1892 SYSTEM BLOCK DIAGRAM (TV) Tuner PIF&SIF Color, intensity and defrecting signal processor Color output Vertical output CRT CRT µ PD17002 µ PD17052 µ PD17053 Digital tuning controller L US MTS µ PC1892 Matrix surround sound processor Power amplifier µ PC1852 Remote control reception amplifier R µ PC1310 µ PC1316C µPC2800A µPC2801A PIN photo diode 2 BLOCK DIAGRAM HPF 820 kΩ 0.082 µ F 28 29 0.1 µ F 2200 pF 0.022 µ F 0.022 µF 1000 pF FC1 FC2 FC3 FC4 3 4 5 1µ F Note 6800 pF Note 0.15 µ F 21 BALANCE CONTROL VCC 10 kΩ 1 510 Ω VOLUME CONTROL 10 kΩ +5 V 10 kΩ + 30 6 2 22 510 Ω 20 19 L+R VOLUME CONTROL 510 Ω 18 LIN + 22 µ F EFFECT CONTROL LPF 1 – + Simulated Simulated/Movie ϕ (L–R) LPF 2 OFFSET ABSORPTION Surround 25 TONE (BASS, TREBLE) CONTROL VOLUME BALANCE CONTROL 14 L OUTPUT L+ϕ (L–R) + 4.7 µ F PS1 PS2 PS3 PS4 MATRIX Movie/ Music PHASE SHIFTER Music L–R ϕ (L–R) DC CONTROL 9 + 4.7 µ F REAR OUTPUT – + RIN + OFF 26 1 VCC 2 1 VCC 2 22 µ F MODE CONTROL TONE (BASS, TREBLE) CONTROL VOLUME BALANCE CONTROL 12 R OUTPUT R– ϕ (L–R) + 4.7 µ F L+R OUTPUT L+R + 4.7 µ F VOLUME CONTROL 23 1 kΩ +5 V 510 Ω EFFECT CONTROL 10 11 15 510 Ω Note 6800 pF Note 0.15 µ F GND 10 kΩ BASS CONTROL TREBLE CONTROL 10 kΩ 17 16 510 Ω +5 V 13 24 27 1 kΩ 7 8 22 µ F + 680 pF MS1 MS2 10 kΩ µPC1892 Note Recommended Precision: ±1 % 3 µPC1892 PIN CONFIGURATIONS (Top View) Supply Voltage Phase Shift Filter1 Phase Shift Filter2 Phase Shift Filter3 Phase Shift Filter4 Offset Filter Mode Select1 Mode Select2 Rear Output R-ch Treble Capacitor R-ch Bass Capacitor R-ch Signal Output L+R-ch Signal Output L-ch Signal Output Ground 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 VCC FC1 FC2 FC3 FC4 OF LF2 MFI MFO LF1 RIN LIN 30 29 28 27 26 25 24 23 22 21 20 19 18 17 16 Low Pass Filter2 Monaural Filter Input Monaural Filter Output Low Pass Filter1 R-ch Signal Input L-ch Signal Input Reference Voltage Effect Control L-ch Treble Capacitor L-ch Bass Capacitor Balance Control Volume Control L+R-ch Volume Control Bass Control Treble Control µ PC1892CT µ PC1892CT-02 MS1 MS2 REARout RTC RBC Rout L + Rout Lout GND RF EFF LTC LBC BAL VOL L+R BAS TBL 4 µPC1892 MODE SELECT CODE Select among OFF, Movie, Music and Simulated mode by MS1 and MS2 (Pins 7 and 8). Code Mode OFF Music Movie Simulated MS1 (Pin 7) L H L H MS2 (Pin 8) L L H H Cautions 1. In the case of changing surround mode and power ON/OFF, mute (approx. 200 ms) must be used for pop noise reduction. 2. Insert resistors between mode select pins (pin 7, 8) and GND, between control pins (pin 16, 17, 18, 19, 20, 23) and GND. 3. Connect a electrolytic capacitor for power supply as close as possible to VCC (pin 1). Remark About "H" and "L", refer to RECOMMENDED OPERATING CONDITIONS. 5 µPC1892 Explanation of Pins (1/4) Pin number/name 1 Power supply 2 3 4 5 Phase Phase Phase Phase shift shift shift shift filter1 filter2 filter3 filter4 VCC (Pins 3, 4 and 5 are same as pin 2.) VCC 5µA VCC 21 kΩ 18 kΩ VCC 10 kΩ 21 kΩ Equivalent circuit Power supply pin. Description Capacitor connection pin which determines time constant of phase shifter. Pin 2 is used for movie, music, simulated mode. Pins 2, 3, 4, 5 is used for movie, simulated mode. Recommended value of capacitor is as follows. Pin 2: 0.1 µF Pin 3: 2200 pF Pin 4, 5: 0.022 µF 3 kΩ 2 6 Offset filter VCC 50 kΩ VCC 25 µ A 10 kΩ 6 + – 1µ F 3 kΩ Capacitor connection pin which absorbs offset voltage generated by phase shifter. 7 Mode select1 8 Mode select2 (Pin 8 is same as pin 7.) 1 kΩ 7 50 kΩ 50 kΩ Surround mode switch pin. Control by pin 7, 8 (2 bit parallel). Input impedance:approx. 100 kΩ. 6 µPC1892 Explanation of Pins (2/4) Pin number/name 9 12 13 14 Rear output R-ch signal output L+R-ch signal output L-ch signal output Equivalent circuit (Pins 12, 13 and 14 are same as pin 9.) VCC 1 kΩ 5 kΩ 9 5 kΩ 10 kΩ 5 kΩ VCC 4.7 µ F + Description 10 R-ch treble capacitor 22 L-ch treble capacitor VCC (Pin 22 is same as pin 10.) 7.5 kΩ 5.8 kΩ VCC 3 kΩ 3 kΩ 3 kΩ 10 kΩ 25 µ A 10 6800 pF (±1 %) 11 R-ch bass capacitor 21 L-ch bass capacitor (Pin 21 is same as pin 1.) 1 2 VCC 7.5 kΩ VCC 5.3 kΩ VCC 3 kΩ 3 kΩ 3 kΩ 10 kΩ 11 0.15 µ F (±1 %) 25 µ A 15 GND GND GND pin. 7 µPC1892 Explanation of Pins (3/4) Pin number/name 16 17 18 19 20 Treble control Bass control L+R-ch volume control Volume control Balance control Equivalent circuit (Pins 17, 18, 19 and 20 are same as pin 16.) VCC 40 µ A Sound control pin. Description 16 75 kΩ 75 kΩ 23 Effect control VCC 40 µ A Surround effect control pin. Input impedance: approx. 100 kΩ. 23 50 kΩ 50 kΩ 24 Reference voltage VCC VCC 20 kΩ 24 + 22 µ F – 20 kΩ 10 kΩ 3 kΩ 25 L-ch signal input 26 R-ch signal input (Pin 26 is same as pin 25.) 1 2 Input impedance: approx. 40 kΩ. VCC VCC 5µA VCC 18.3 kΩ – + 25 18.3 kΩ 22 µ F 8 µPC1892 Explanation of Pins (4/4) Pin number/name 27 Low pass filter1 28 Monaural filter output 29 Monaural filter input VCC Equivalent circuit Description Pins 28, 29 are for HPF at simulated mode. Connect capacitor and resistor between pin 28 and 29. VCC 3 kΩ 18 kΩ 5 µA VCC 27 680 pF 1 kΩ VCC10 kΩ VCC VCC 47 5 µA 15 kΩ kΩ VCC 15 kΩ VCC 1 2 47 kΩ 10 kΩ 28 29 0.082 µ F 820 kΩ 30 Low pass filter2 VCC 17.7 kΩ VCC 3 kΩ VCC 5µ A 10 kΩ 30 1000 pF 9 µPC1892 ELECTRICAL CHARACTERISTICS Absolute Maximum Ratings (at TA = 25 °C) Parameter Supply voltage Input signal level Control pin voltage Package power dissipation Operating temperature Storage temperature Symbol VCC VIN VCONT PD TA Tstg Conditions No signal, OFF mode Pin 25, 26 Input voltage Pin 16, 17, 18, 19, 20, 23 Apply voltage T A = 7 5 °C VCC = 12 V Ratings 14.0 VCC VCC + 0.2 640 –20 to +75 –40 to +125 Unit V V V mW °C °C Recommended Operating Conditions Parameter Supply voltage Input signal level 1 Symbol VCC VIN1 Conditions No signal, OFF mode VCC = 12 V, OFF mode, T.H.D = 1 % Volume control voltage = 5.0 V Balance, bass, treble control voltage = 2.5 V VCC = 12 V, T.H.D = 1 % L+R volume control voltage = 5.0 V AC load impedance which can be driven by output of pin 9, 12, 13, 14 Pin 7, 8 Apply voltage Pin 7, 8 Apply voltage Pin 23 Upper limit voltage Pin 23 Lower limit voltage Pin 16, 17, 18, 19, 20 Apply voltage Pin 16, 17, 18, 19, 20 Apply voltage MIN. 10.8 – TYP. 12.0 1.4 MAX. 13.2 8.5 Unit V Vp-p Input signal level 2 Output load impedance Mode select pin voltage (H) Mode select pin voltage (L) Effect pin voltage (H) Effect pin voltage (L) Control pin voltage (H) Control pin voltage (L) VIN2 PL VMSH VMSL VEFFH VEFFL VCONTH VCONTL – 10 3.5 0 – 0 – 0 1.4 8.5 Vp-p kΩ 5.0 0 5.0 0 5.0 0 VCC 2.0 VCC – VCC – V V V V V V 10 µPC1892 Electrical characteristics (TA = 25 °C, RH ≤ 70 %, VCC = 12 V) General Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode OFF OFF OFF – 23 8.5 – – Control pin voltage (V) Balance Volume Treble – M M – Bass – M M – Supply current Maximum output voltage Distortion factor L+R distortion factor ICC VOM T.H.D. T.H.D. (L+R) No signal VCC = 12 V, T.H.D. = 1 % VIN = 0.5 Vr.m.s., f = 1 kHz VIN = 0.5 Vr.m.s., f = 1 kHz, L+R volume control voltage: 5.0 V – H H – – M M – 29 9.9 0.1 0.1 37 mA Vp-p 0.5 0.5 % % Note 1. H: 5.0 V, M: 2.5 V, L: 0 V, –: Undefined 2. OFF: OFF mode, –: Undefined 11 µPC1892 µPC1892CT Volume control, tone control block (1/1) Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode OFF Control pin voltage (V) Balance Volume Treble M Bass M Volume attenuation ATTVOL VIN = 0.5 Vr.m.s., f = 1 kHz, Volume control voltage: 0.2 V 0 dB: Volume control voltage = H Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, L+R volume control voltage: 0.2 V 0 dB: L+R volume control voltage = H Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 4.5 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 0.5 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 100 Hz, Bass control voltage: 4.5 V 0 dB: Bass control voltage = M VIN = 0.5 Vr.m.s., f = 100 Hz, Bass control voltage: 0.5 V 0 dB: Bass control voltage = M VIN = 0.5 Vr.m.s., f = 10 kHz, Treble control voltage: 4.5 V 0 dB: Treble control voltage = M VIN = 0.5 Vr.m.s., f = 10 kHz, Treble control voltage: 0.5 V 0 dB: Treble control voltage = M H ↓ 0.2 – M – –80 –72 dB L+R volume attenuation ATTL+RVOL – – – – – –85 –75 dB Balance attenuation L-ch ATTBALL H M ↓ 4.5 M ↓ 0.5 M M M OFF –22 –18 –12 dB Balance attenuation R-ch ATTBALR H M M OFF –22 –18 –12 dB Low-band boost control VBB H M M ↓ 4.5 M ↓ 0.5 M OFF 7 10 13 dB Low-band cut control VBC H M M OFF –13 –10 –7 dB High-band boost control VTB H M M ↓ 4.5 M ↓ 0.5 OFF 7 10 13 dB High-band cut control VTC H M M OFF –13 –10 –7 dB Note 1. H: 5.0 V, M: 2.5 V, L: 0 V, –: Undefined, The alphanumeric numbers in this table represent the level (V). 2. OFF: OFF mode, –: Undefined 12 µPC1892 µPC1892CT-02 Volume control, tone control block (1/1) Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode OFF Control pin voltage (V) Balance Volume Treble M Bass M Volume attenuation ATTVOL VIN = 0.5 Vr.m.s., f = 1 kHz, Volume control voltage: 0.2 V 0 dB: Volume control voltage = H Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, L+R volume control voltage: 0.2 V 0 dB: L+R volume control voltage = H Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 4.3 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 5 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 0.7 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 1 kHz, Balance control voltage: 0 V 0 dB: Balance control voltage = M Filter: JIS-A VIN = 0.5 Vr.m.s., f = 100 Hz, Bass control voltage: 4.5 V 0 dB: Bass control voltage = M VIN = 0.5 Vr.m.s., f = 100 Hz, Bass control voltage: 0.5 V 0 dB: Bass control voltage = M VIN = 0.5 Vr.m.s., f = 10 kHz, Treble control voltage: 4.5 V 0 dB: Treble control voltage = M VIN = 0.5 Vr.m.s., f = 10 kHz, Treble control voltage: 0.5 V 0 dB: Treble control voltage = M H ↓ 0.2 – M – – –90 dB L+R volume attenuation ATTL+RVOL – – – – – –85 –75 dB Balance attenuation 1 L-ch ATTBALL1 H M ↓ 4.3 M ↓ 5.0 M ↓ 0.7 M ↓ 0.0 M M M OFF –19 –16 –10 dB Balance attenuation 2 L-ch ATTBALL2 H M M OFF – – –90 dB Balance attenuation 1 R-ch ATTBALR1 H M M OFF –19 –16 –10 dB Balance attenuation 2 R-ch ATTBALR2 H M M OFF – – –90 dB Low-band boost control VBB H M M ↓ 4.5 M ↓ 0.5 M OFF 7 10 13 dB Low-band cut control VBC H M M OFF –13 –10 –7 dB High-band boost control VTB H M M ↓ 4.5 M ↓ 0.5 OFF 7 10 13 dB High-band cut control VTC H M M OFF –13 –10 –7 dB Note 1. H: 5.0 V, M: 2.5 V, L: 0 V, –: Undefined, The alphanumeric numbers in this table represent the level (V). 2. OFF: OFF mode, –: Undefined 13 µPC1892 Matrix surround block (1/3) Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode – –1 Control pin voltage (V) Balance Volume Treble – Bass – In-phase gain L+Rout In-phase gain OFF mode In-phase gain Movie mode 1 In-phase gain Movie mode 2 In-phase gain Music mode 1 In-phase gain Music mode 2 In-phase gain Simulated mode 1 L-ch In-phase gain Simulated mode 2 L-ch In-phase gain Simulated mode 3 L-ch In-phase gain Simulated mode 1 R-ch In-phase gain Simulated mode 2 R-ch In-phase gain Simulated mode 3 R-ch L, R in-phase gain difference OFF mode L, R in-phase gain difference Movie mode GL+R VIN = 0.5 Vr.m.s., f = 1 kHz, L+R volume control voltage = H 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = H 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = H 0 dB: Input level VIN = 0.5 Vr.m.s., f = 250 Hz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 3.6 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 250 Hz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 3.6 kHz, Effect control voltage = M 0 dB: Input level VIN = 0.5 Vr.m.s., f = 1 kHz, DGOFF = (RIN→ROUT) – (LIN→LOUT) VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M DGMOV = (RIN→ROUT) – (LIN→LOUT) – – 0 +1 dB GOFF GMOV1 H H M M M M M M OFF MOV –1.5 –0.5 +0.5 dB dB +4.0 +8.6 +11.0 GMOV2 H M M M MOV +6.0 +10.0 +12.5 dB GMUS1 H M M M MUS +4.9 +7.0 +8.9 dB GMUS2 H M M M MUS +5.9 +8.1 +10.1 dB GSIML1 H M M M SIM +1.7 +4.2 +6.1 dB GSIML2 H M M M SIM – –5.2 –1.2 dB GSIML3 H M M M SIM +4.5 +7.3 +9.4 dB GSIMR1 H M M M SIM – –7.0 –1.0 dB GSIMR2 H M M M SIM +1.7 +3.6 +5.2 dB GSIMR3 H M M M SIM – –7.6 +0.9 dB DGOFF H M M M OFF –1 0 +1 dB DGMOV H M M M MOV –2 0 +2 dB Note 1. H: 5 V, M: 2.5 V, L: 0 V, –: Undefined 2. OFF: OFF mode, MOV: Movie mode, MUS: Music mode, SIM: Simulated mode, –: Undefined 14 µPC1892 Matrix surround block (2/3) Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode MUS –2 Control pin voltage (V) Balance Volume Treble M Bass M L, R in-phase gain difference Music mode Rear output gain 1 DGMUS VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M DGMUS = (RIN→ROUT) – (LIN→LOUT) VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M GREAR1 = RIN (LIN)→REARout VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = H GREAR2 = RIN (LIN)→REARout VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = M GREAR3 = RIN (LIN)→REARout VIN = 0.5 Vr.m.s., f = 1 kHz, Effect control voltage = H GREAR4 = RIN (LIN)→REARout DIN/AUDIO filter used. Input terminal resistor (600 Ω) L+R volume control voltage = H DIN/AUDIO filter used. Input terminal resistor (600 Ω) DIN/AUDIO filter used. Input terminal resistor (600 Ω) DIN/AUDIO filter used. Input terminal resistor (600 Ω) DIN/AUDIO filter used. Input terminal resistor (600 Ω) VIN = 0.5 Vr.m.s., f = 1 kHz, BPF (1 kHz) used. CT = LIN→ROUT, RIN→LOUT Input terminal resistor (600 Ω) No signal OFF mode → Music mode OFF mode → Movie mode OFF mode → Simulated mode Simulated mode → Music mode Simulated mode → Movie mode Music mode → Movie mode H M 0 +2 dB GREAR1 – – – – MUS –5.0 –3.0 –1.1 dB Rear output gain 2 GREAR2 – – – – MUS –3.0 –1.2 +0.5 dB Rear output gain 3 GREAR3 – – – – MOV –0.4 +1.6 +3.5 dB Rear output gain 4 GREAR4 – – – – MOV +1.4 +3.2 +4.9 dB Output noise L+Rout Output noise OFF mode Output noise Movie mode Output noise Music mode Output noise Simulated mode Crosstalk NOL+R – – – – – – 25 80 µVr.m.s. NOOFF NOMOV NOMUS NOSIM CT H H H H H M M M M M M M M M M M M M M M OFF MOV MUS SIM OFF – – – – – 25 0.1 0.1 0.1 –80 80 µVr.m.s. 0.3 mVr.m.s. 0.3 mVr.m.s. 0.3 mVr.m.s. –70 dB Inter-mode offset VOSM H M M M Note 3 –75 0.0 +75 mV Note 1. H: 5 V, M: 2.5 V, L: 0 V, –: Undefined 2. OFF: OFF mode, MOV: Movie mode, MUS: Music mode, SIM: Simulated mode, –: Undefined 3. Refer to test conditions. 15 µPC1892 Matrix surround block (3/3) Parameter Symbol Test conditions Note 1 Note 1 Note 2 MIN. TYP. MAX. Unit Surround mode OFF –100 Control pin voltage (V) Balance Volume Treble M Bass M DC offset 1 VDCOS1 No signal H ↓ L – M 0.0 +100 mV DC offset 2 VDCOS2 No signal L+R volume control voltage =H→L No signal – – – – –100 0.0 +100 mV DC offset 3 VDCOS3 H M ↓ L or H M M M OFF –100 0.0 +100 mV DC offset 4 VDCOS4 No signal H M M ↓ L or H M OFF –100 0.0 +100 mV DC offset 5 VDCOS5 No signal H M M ↓ L or H OFF –100 0.0 +100 mV Note 1. H: 5 V, M: 2.5 V, L: 0 V. 2. OFF: OFF mode, MOV: Movie mode, MUS: Music mode, SIM: Simulated mode. 16 µPC1892 Electrical Characteristics Measurement List (Supplement) (at TA = 25 °C, RH ≤ 70 %, VCC = 12 V) Recommended Operating Conditions Note 1 Parameter Symbol Conditions Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 BAS 2.5 L+R – EFF – mode Input signal level 1 VIN1 Input level when distortion factor of LOUT (Pin 14) is 1 %, LIN (Pin 25) : f = 1 kHz Input level when distortion factor of ROUT (Pin 12) is 1 %, RIN (Pin 26) : f = 1 kHz Input level when distortion factor of L+ROUT (Pin 13) is 1 %, LIN, RIN (Pin 25, 26) : f = 1 kHz OFF Input signal level 2 VIN2 OFF – – – – 5.0 – Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined Electrical characteristics measurement: General Note 1 Parameter Symbol Test conditions Surround Control pin voltage (V) Note 2 VOL 5.0 5.0 BAL 2.5 2.5 TRE 2.5 2.5 BAS 2.5 2.5 L+R 5.0 – EFF 2.5 – mode Supply current Distortion factor ICC T.H.D. Current flowing to VCC (Pin 1) No signal L-channel Distortion factor of LOUT (Pin 14) LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. R-channel Distortion factor of ROUT (Pin 12) RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. L+R-channel Distortion factor of L+ROUT (Pin 13) LIN (Pin 25), RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. OFF OFF L+R distortion factor T.H.D. (L+R) OFF – – – – 5.0 – Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 17 µPC1892 Electrical characteristics measurement: µPC1892CT Volume control, tone control block (1/3) Note 1 Parameter Symbol Test conditions VATT VREF Control pin voltage (V) Note 2 VOL 5.0 ↓ 0.2 BAL 2.5 TRE 2.5 BAS 2.5 L+R – EFF – Surround mode Volume attenuation ATTVOL ATTVOL = 20 log OFF L-channel LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Volume control voltage : 5.0 V) VATT : LOUT (Pin 14) (Volume control voltage : 0.2 V) JIS-A filter used. R-channel RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Volume control voltage : 5.0 V) VATT : ROUT (Pin 12) (Volume control voltage : 0.2 V) JIS-A filter used. L+R volume attenuation ATTL+R ATTL+R = 20 log VL+RATT OFF – – – – VL+RREF LIN, RIN (Pin 25, 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VL+RREF : L+ROUT (Pin 13) (L+R volume control voltage : 5.0 V) VL+RATT : L+ROUT (Pin 13) (L+R volume control voltage : 0.2 V) JIS-A filter used. VATT OFF 5.0 2.5 ↓ 4.5 2.5 2.5 5.0 ↓ 0.2 – Balance attenuation Lch/Rch ATTBALL ATTBAL = 20 log ATTBALR VREF L-channel LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Balance control voltage : 2.5 V) VATT : LOUT (Pin 14) (Balance control voltage : 4.5 V) JIS-A filter used. R-channel RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Balance control voltage : 2.5 V) VATT : ROUT (Pin 12) (Balance control voltage : 0.5 V) JIS-A filter used. – – 5.0 2.5 ↓ 0.5 2.5 2.5 – – Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 18 µPC1892 Electrical characteristics measurement: µPC1892CT Volume control, tone control block (2/3) Note 1 Parameter Symbol Test conditions Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 BAS 2.5 ↓ 4.5 L+R – EFF – mode Low-band boost control VBB VBB = 20 log VBST VREF OFF L-channel LIN (Pin 25) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Bass control voltage : 2.5 V) VBST : LOUT (Pin 14) (Bass control voltage : 4.5 V) R-channel RIN (Pin 26) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Bass control voltage : 2.5 V) VBST : ROUT (Pin 12) (Bass control voltage : 4.5 V) Low-band cut control VBC VBC = 20 log VATT VREF OFF 5.0 2.5 2.5 L-channel LIN (Pin 25) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Bass control voltage : 2.5 V) VATT : LOUT (Pin 14) (Bass control voltage : 0.5 V) R-channel RIN (Pin 26) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Bass control voltage : 2.5 V) VATT : ROUT (Pin 12) (Bass control voltage : 0.5 V) High-band boost control VTB VTB = 20 log VBST OFF 5.0 2.5 2.5 ↓ 4.5 2.5 ↓ 0.5 – – 2.5 – – VREF L-channel LIN (Pin 25) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Treble control voltage : 2.5 V) VBST : LOUT (Pin 14) (Treble control voltage : 4.5 V) R-channel RIN (Pin 26) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Treble control voltage : 2.5 V) VBST : ROUT (Pin 12) (Treble control voltage : 4.5 V) Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 19 µPC1892 Electrical characteristics measurement: µPC1892CT Volume control, tone control block (3/3) Note 1 Parameter Symbol Test conditions Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 ↓ 0.5 BAS 2.5 L+R – EFF – mode High-band cut control VTC VTC = 20 log VATT VREF OFF L-channel LIN (Pin 25) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Treble control voltage : 2.5 V) VATT : LOUT (Pin 14) (Treble control voltage : 0.5 V) R-channel RIN (Pin 26) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Treble control voltage : 2.5 V) VATT : ROUT (Pin 12) (Treble control voltage : 0.5 V) Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 20 µPC1892 Electrical characteristics measurement: µPC1892CT-02 Volume control, tone control block (1/3) Note 1 Parameter Symbol Test conditions VATT VREF Control pin voltage (V) Note 2 VOL 5.0 ↓ 0.2 BAL 2.5 TRE 2.5 BAS 2.5 L+R – EFF – Surround mode Volume attenuation ATTVOL ATTVOL = 20 log OFF L-channel LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Volume control voltage : 5.0 V) VATT : LOUT (Pin 14) (Volume control voltage : 0.2 V) JIS-A filter used. R-channel RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Volume control voltage : 5.0 V) VATT : ROUT (Pin 12) (Volume control voltage : 0.2 V) JIS-A filter used. L+R volume attenuation ATTL+R ATTL+R = 20 log VL+RATT OFF – – – – VL+RREF LIN, RIN (Pin 25, 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VL+RREF : L+ROUT (Pin 13) (L+R volume control voltage : 5.0 V) VL+RATT : L+ROUT (Pin 13) (L+R volume control voltage : 0.2 V) JIS-A filter used. 5.0 ↓ 0.2 – Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 21 µPC1892 Electrical characteristics measurement: µPC1892CT-02 Volume control, tone control block (2/3) Note 1 Parameter Symbol Test conditions Surround Control pin voltage (V) Note 2 VOL BAL TRE BAS L+R EFF mode Balance attenuation Lch/Rch ATTBALL1 ATTBAL = 20 log VATT VREF OFF ATTBALL2 ATTBALR1 ATTBALR2 L-channel 1 LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Balance control voltage : 2.5 V) VATT : LOUT (Pin 14) (Balance control voltage : 4.3 V) JIS-A filter used. L-channel 2 LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Balance control voltage : 2.5 V) VATT : LOUT (Pin 14) (Balance control voltage : 5.0 V) JIS-A filter used. R-channel 1 RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Balance control voltage : 2.5 V) VATT : ROUT (Pin 12) (Balance control voltage : 0.7 V) JIS-A filter used. R-channel 2 RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Balance control voltage : 2.5 V) VATT : ROUT (Pin 12) (Balance control voltage : 0.0 V) JIS-A filter used. VBB = 20 log VBST VREF OFF 5.0 2.5 ↓ 4.3 2.5 2.5 – – 5.0 2.5 ↓ 5.0 2.5 2.5 – – 5.0 2.5 ↓ 0.7 2.5 2.5 – – 5.0 2.5 ↓ 0.0 2.5 2.5 – – Low-band boost control VBB 5.0 2.5 2.5 2.5 ↓ 4.5 – – L-channel LIN (Pin 25) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Bass control voltage : 2.5 V) VBST : LOUT (Pin 14) (Bass control voltage : 4.5 V) R-channel RIN (Pin 26) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Bass control voltage : 2.5 V) VBST : ROUT (Pin 12) (Bass control voltage : 4.5 V) Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 22 µPC1892 Electrical characteristics measurement: µPC1892CT-02 Volume control, tone control block (3/3) Note 1 Parameter Symbol Test conditions VATT VREF Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 BAS 2.5 ↓ 0.5 L+R – EFF – mode Low-band cut control VBC VBC = 20 log OFF L-channel LIN (Pin 25) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Bass control voltage : 2.5 V) VATT : LOUT (Pin 14) (Bass control voltage : 0.5 V) R-channel RIN (Pin 26) : f = 100 Hz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Bass control voltage : 2.5 V) VATT : ROUT (Pin 12) (Bass control voltage : 0.5 V) High-band boost control VTB VTB = 20 log VBST VREF OFF 5.0 2.5 2.5 ↓ 4.5 2.5 – – L-channel LIN (Pin 25) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Treble control voltage : 2.5 V) VBST : LOUT (Pin 14) (Treble control voltage : 4.5 V) R-channel RIN (Pin 26) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Treble control voltage : 2.5 V) VBST : ROUT (Pin 12) (Treble control voltage : 4.5 V) High-band cut control VTC VTC = 20 log VATT VREF OFF 5.0 2.5 L-channel LIN (Pin 25) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : LOUT (Pin 14) (Treble control voltage : 2.5 V) VATT : LOUT (Pin 14) (Treble control voltage : 0.5 V) R-channel RIN (Pin 26) : f = 10 kHz, VIN = 0.5 Vr.m.s. VREF : ROUT (Pin 12) (Treble control voltage : 2.5 V) VATT : ROUT (Pin 12) (Treble control voltage : 0.5 V) 2.5 ↓ 0.5 2.5 – – Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 23 µPC1892 Electrical characteristics measurement: Matrix block (1/5) Note 1 Parameter Symbol Test conditions Surround Control pin voltage (V) Note 2 VOL – BAL – TRE – BAS – L+R 5.0 EFF – mode In-phase gain L+ROUT GL+R GL+R : Output level of L+ROUT (Pin 13) LIN (Pin 25), RIN(Pin 26) : f = 1 kHz VIN = 0.5 Vr.m.s. 0 dB : Input level LIN (Pin 25), RIN (Pin 26) L -channel GOFF : Output level of LOUT (Pin 14) LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of LIN (Pin 25) R -channel GOFF : Outpt level of ROUT (Pin 12) RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of RIN (Pin 26) In-phase gain Movie mode 1/2 GMOV1 GMOV2 L -channel GMOV : Output level of LOUT (Pin 14) LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of LIN (Pin 25) R -channel GMOV : Output level of ROUT (Pin 12) RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of RIN (Pin 26) L -channel GMUS : Output level of LOUT (Pin 14) LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of LIN (Pin 25) R -channel GMUS : Output level of ROUT (Pin 12) RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s. 0 dB : Input level of RIN (Pin 26) L -channel GSIM : Output level of LOUT (Pin 14) LIN (Pin 25) : f = 250 Hz/1 kHz/3.6 kHz VIN = 0.5 Vr.m.s. 0 dB : Input level of LIN (Pin 25) R -channel GSIM : Output level of ROUT (Pin 12) RIN (Pin 26) : f = 250 Hz/1 kHz/3.6 kHz VIN = 0.5 Vr.m.s. 0 dB : Input level of RIN (Pin 26) MUS MOV OFF In-phase gain OFF mode GOFF OFF 5.0 2.5 2.5 2.5 – – 5.0 2.5 2.5 2.5 – 2.5 or 5.0 In-phase gain Music mode 1/2 GMus1 GMus2 5.0 2.5 2.5 2.5 – 2.5 or 5.0 In-phase gain Simulated mode L-ch 1/2/3 GSIML1 GSIML2 GSIML3 SIM 5.0 2.5 2.5 2.5 – 2.5 In-phase gain Simulated mode R-ch 1/2/3 GSIMR1 GSIMR2 GSIMR3 SIM 5.0 2.5 2.5 2.5 – 2.5 Note 1. OFF: OFF mode, MOV: Movie mode, MUS: Music mode, SIM: Simulated mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 24 µPC1892 Electrical characteristics measurement: Matrix block (2/5) Note 1 Parameter Symbol Test conditions VROUT VLOUT Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 BAS 2.5 L+R – EFF 2.5 mode L, R in-phase gain difference OFF mode Movie mode Music mode DGOFF DGMOV DGMUS DG = 20 log – 20 log VRIN VLIN VROUT : Voltage of ROUT (Pin 12) VRIN : Voltage of RIN (Pin 26) (0.5 Vr.m.s., f = 1 kHz) VLOUT : Voltage of LOUT (Pin 14) VLIN : Voltage of LIN (Pin 25) (0.5 Vr.m.s., f = 1 kHz) REAROUT VIN OFF MOV MUS Rear output gain 1/2/3/4 GREAR1 GREAR2 GREAR3 GREAR4 GREAR = 20 log MUS MOV 5.0 2.5 2.5 2.5 – L-channel VIN : Voltage of LIN (Pin 25) (0.5 Vr.m.s., f = 1 kHz) REAROUT : Voltage of REAROUT (Pin 9) R-channel VIN : Voltage of RIN (Pin 26) (0.5 Vr.m.s., f = 1 kHz) REAROUT : Voltage of REAROUT (Pin 9) NOOFF : Voltage of LOUT (Pin 14), ROUT (PIn 12) through DIN/AUDIO filter. NOL+R : Voltage of L+ROUT (Pin 13) through DIN/AUDIO filter. LIN (Pin 25), RIN (Pin 26) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). NOMOV : Voltage of LOUT (Pin 14), ROUT (Pin 12) through DIN/AUDIO filter. LIN (Pin 25), RIN (Pin 26) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). NOMUS : Voltage of LOUT (Pin 14), ROUT (Pin 12) through DIN/AUDIO filter. LIN (Pin 25), RIN (Pin 26) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). NOSIM : Voltage of LOUT (Pin 14), ROUT (Pin 12) through DIN/AUDIO filter. LIN (Pin 25), RIN (Pin 26) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). OFF 5.0 2.5 2.5 2.5 5.0 2.5 or 5.0 Output noise OFF mode L+ROUT NOOFF NOL+R – Output noise Movie mode NOMOV MOV 5.0 2.5 2.5 2.5 – 2.5 Output noise Music mode NOMUS MUS 5.0 2.5 2.5 2.5 – 2.5 Output noise Simulated mode NOSIM SIM 5.0 2.5 2.5 2.5 – 2.5 Note 1. OFF: OFF mode, MOV: Movie mode, MUS: Music mode, SIM: Simulated mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 25 µPC1892 Electrical characteristics measurement: Matrix block (3/5) Note 1 Parameter Symbol Test conditions VLIN VRIN Surround Control pin voltage (V) Note 2 VOL 5.0 BAL 2.5 TRE 2.5 BAS 2.5 L+R – EFF – mode Crosstalk CT CT = 20 log OFF L-channel VLIN : Voltage of LOUT (Pin 14) VRIN : Voltage of ROUT (Pin 12) LIN (Pin 25) : f = 1 kHz, VIN = 0.5 Vr.m.s., BPF (f = 1 kHz) used RIN (Pin 26) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). R-channel VLIN : Voltage of LOUT (Pin 14) VRIN : Voltage of ROUT (Pin 12) RIN (Pin 26) : f = 1 kHz, VIN = 0.5 Vr.m.s., BPF (f = 1 kHz) used LIN (Pin 25) : Connect to the GND with electrolytic capacitor (22 µF) and resistor (600 Ω). Note 1. OFF: OFF mode 2. VOL: Volume control voltage, BAL: Balance control voltage, TRE: Treble control voltage, BAS: Bass control voltage, L+R: L+R volume control voltage, EFF: Effect control voltage, –: Undefined 26 µPC1892 Electrical characteristics measurement: Matrix block (4/5) Parameter Inter-mode offset Symbol VOSM Test conditions (OFF : OFF mode, MUS : Music mode, MOV : Movie mode, SIM : Simulated mode) VOSM (OFF→MUS) : Difference between VDC (OFF) and VDC (MUS). VDC (OFF) : DC voltage of LOUT (Pin 14). (OFF) VDC (MUS) : DC voltage of LOUT (Pin 14). (MUS) VOSM (OFF→MOV) : Difference between VDC (OFF) and VDC (MOV). VDC (OFF) : DC voltage of LOUT (Pin 14). (OFF) VDC (MOV) : DC voltage of LOUT (Pin 14). (MOV) VOSM (OFF→SIM) : Difference between VDC (OFF) and VDC (SIM). VDC (OFF) : DC voltage of LOUT (Pin 14). (OFF) VDC (SIM) : DC voltage of LOUT (Pin 14). (SIM) VOSM (SIM→MUS) : Difference between VDC (SIM) and VDC (MUS). VDC (SIM) : DC voltage of LOUT (Pin 14). (SIM) VDC (MUS) : DC voltage of LOUT (Pin 14). (MUS) VOSM (SIM→MOV) : Difference between VDC (SIM) and VDC (MOV). VDC (SIM) : DC voltage of LOUT (Pin 14). (SIM) VDC (MOV) : DC voltage of LOUT (Pin 14). (MOV) VOSM (MUS→MOV) : Difference between VDC (MUS) and VDC (MOV). VDC (MUS) : DC voltage of LOUT (Pin 14). (MUS) VDC (MOV) : DC voltage of LOUT (Pin 14). (MOV) Execute the same operation for Rout (Pin 12). 27 µPC1892 Electrical characteristics measurement: Matrix block (5/5) Surround mode OFF (Pin 12) V) (Pin 12) V) OFF Parameter DC offset 1 Symbol VDCOS1 Test conditions VDCOS1 = VVOLH – VVOLL VVOLH: Voltage of Lout (Pin 14), Rout (Volume control voltage = 5 VVOLL: Voltage of Lout (Pin 14), Rout (Volume control voltage = 0 DC offset 2 VDCOS2 VDCOS2 = VL+RH – VL+RL VL+RH: Voltage of L+Rout (Pin 13). (L+R volume control voltage = 5 V) VL+RL: Voltage of L+Rout (Pin 13). (L+R volume control voltage = 0 V) VDCOS3 = VBALM – VBALL VBALM: Voltage of Lout (Pin 14), Rout (Pin 12) (Balance control voltage = 2.5 V) VBALL: Voltage of Lout (Pin 14), Rout (Pin 12) (Balance control voltage = 0 V) VDCOS3 = VBALM – VBALH VBALM: Voltage of Lout (Pin 14), Rout (Pin 12) (Balance control voltage = 2.5 V) VBALH: Voltage of Lout (Pin 14), Rout (Pin 12) (Balance control voltage = 5 V) DC offset 3 VDCOS3 OFF DC offset 4 VDCOS4 VDCOS4 = VBASM – VBASL VBASM: Voltage of Lout (Pin 14), Rout (Pin 12) (Bass control voltage = 2.5 V) VBASL: Voltage of Lout (Pin 14), Rout (Pin 12) (Bass control voltage = 0 V) VDCOS4 = VBASM – VBASH VBASM: Voltage of Lout (Pin 14), Rout (Pin 12) (Bass control voltage = 2.5 V) VBASH: Voltage of Lout (Pin 14), Rout (Pin 12) (Bass control voltage = 5 V) OFF DC offset 5 VDCOS5 VDCOS5 = VTREM – VTREL VTREM: Voltage of Lout (Pin 14), Rout (Pin 12) (Treble control voltage = 2.5 V) VTREL: Voltage of Lout (Pin 14), Rout (Pin 12) (Treble control voltage = 0 V) VDCOS5 = VTREM – VTREH VTREM: Voltage of Lout (Pin 14), Rout (Pin 12) (Treble control voltage = 2.5 V) VTREH: Voltage of Lout (Pin 14), Rout (Pin 12) (Treble control voltage = 5 V) OFF Note OFF: OFF mode 28 µPC1892 FREQUENCY RESPONSE CHARACTERISTICS IN EACH MODE (at TA = 25 °C) 1. OFF Mode (L-ch, R-ch) VCC = 12 V VIN = 1.4 VP-P 8 6 4 Gain G (dB) 2 0 –2 –4 –6 100 1k Frequency f (Hz) 10 k 29 µPC1892 2. Movie Mode 12 8 4 0 Gain G (dB) -4 VCC = 12 V VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VL+R = 5.0 V VBAL = 2.5 V VBAS = 2.5 V VTRE = 2.5 V CFC1 = 0.1 µ F CFC2 = 2200 pF CFC3 = 0.022 µ F CFC4 = 0.022 µ F VEFF = 5.0 V VEFF = 2.5 V -8 -12 -16 -20 100 1k Frequency f (Hz) 10 k 3. Music Mode 12 8 4 0 Gain G (dB) VCC = 12 V VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VL+R = 5.0 V VBAL = 2.5 V VBAS = 2.5 V VTRE = 2.5 V CFC1 = 0.1 µ F VEFF = 5.0 V VEFF = 2.5 V -4 -8 -12 -16 -20 100 1k Frequency f (Hz) 10 k Remark VVOL: Volume control voltage, VBAL: Balance control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VEFF: Effect control voltage, VL+R: L+R volume control voltage, CFC1, CFC2, CFC3, CFC4: External capacitance connected to FC1 to FC4 (Pin 2 to 5). 30 µPC1892 4. Simulated Mode (L-ch) 12 8 4 0 Gain G (dB) -4 VCC = 12 V VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VL+R = 5.0 V VBAL = 2.5 V VBAS = 2.5 V VTRE = 2.5 V CFC1 = 0.1 µ F CFC2 = 2200 pF CFC3 = 0.022 µ F CFC4 = 0.022 µ F VEFF = 5.0 V VEFF = 2.5 V -8 -12 -16 -20 100 1k Frequency f (Hz) 10 k 5. Simulated Mode (R-ch) 12 8 4 0 Gain G (dB) -4 VCC = 12 V VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VL+R = 5.0 V VBAL = 2.5 V VBAS = 2.5 V VTRE = 2.5 V CFC1 = 0.1 µ F CFC2 = 2200 pF CFC3 = 0.022 µ F CFC4 = 0.022 µ F VEFF = 5.0 V VEFF = 2.5 V -8 -12 -16 -20 100 1k Frequency f (Hz) 10 k Remark VVOL: Volume control voltage, VBAL: Balance control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VEFF: Effect control voltage, VL+R: L+R volume control voltage, CFC1, CFC2, CFC3, CFC4: External capacitance connected to FC1 to FC4 (Pin 2 to 5). 31 µPC1892 CHARACTERISTICS OF PHASE SHIFTER AND REAR OUTPUT (at TA = 25 °C) 2. Movie Mode L R 0 Phase Rear output +100 R L R VCC = 12 V VVOL = 5.0 V VL+R = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VBAL = 2.5 V VEFF = 2.5 V VIN = 1.4 VP-P (=0 dB) CFC1 = 0.1 µ F CFC2 = 2200 pF CFC3 = 0.022 µ F CFC4 = 0.022 µ F REARout (Pin9) -10 0 L Phase -20 -100 10 30 50 70 100 300 500700 1 k Frequency f (Hz) 3k 5 k 7 k10 k 20 k 3. Music Mode R L VCC = 12 V VVOL = 5.0 V VL+R = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VBAL = 2.5 V VEFF = 2.5 V VIN = 1.4 VP-P (=0 dB) CFC1 = 0.1 µ F REARout (Pin9) 0 Phase +100 Rear output -10 L 0 -20 Phase -100 10 30 50 70 100 300 500700 1 k Frequency f (Hz) 3k 5 k 7 k10 k 20 k Remark VVOL: Volume control voltage, VL+R: L+R volume control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VBAL: Balance control voltage, VEFF: Effect control voltage, CFC1, CFC2, CFC3, CFC4: External capacitance connected to FC1 to FC4 (Pin 2 to 5). 32 Phase φ (deg) Gain G (dB) Phase φ (deg) Gain G (dB) µPC1892 3. Simulated Mode VCC = 12 V VVOL = 5.0 V VL+R = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VBAL = 2.5 V VEFF = 2.5 V VIN = 1.4 VP-P (=0 dB) CFC1 = 0.1 µ F CFC2 = 2200 pF CFC3 = 0.022 µ F CFC4 = 0.022 µ F REARout (Pin9) Rear output 0 +100 -10 Phase 0 -20 -100 10 30 50 70 100 300 500700 1 k Frequency f (Hz) 3k 5 k 7 k10 k 20 k Remark VVOL: Volume control voltage, VL+R: L+R volume control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VBAL: Balance control voltage, VEFF: Effect control voltage, CFC1, CFC2, CFC3, CFC4: External capacitance connected to FC1 to FC4 (Pin 2 to 5). Phase φ (deg) Gain G (dB) 33 µPC1892 CONTROL CHARACTERISTICS 1. Volume Control Characteristics (Lch, Rch) (1) µPC1892CT -0 -20 Attenuation (dB) -40 OFF mode f = 1 kHz VIN = 1.4 VP-P (=0 dB) VBAS = 2.5 V VTRE = 2.5 V VEFF = 2.5 V VBAL = 2.5 V VT = 2.5 V JIS-A filter used -60 -80 -100 0 1 2 3 4 5 Volume Control Voltage (V) (2) µPC1892CT-02 -0 -20 Attenuation (dB) -40 -60 OFF mode f = 1 kHz VIN = 1.4 VP-P (=0 dB) VBAS = 2.5 V VTRE = 2.5 V VEFF = 2.5 V VBAL = 2.5 V VT = 2.5 V JIS-A filter used -80 -100 0 1 2 3 4 5 Volume Control Voltage (V) Remark LL+R: L+R volume control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VEFF: Effect control voltage, VBAL: Balance control voltage, VVOL: Volume control voltage, VT: Tone control voltage. 34 µPC1892 2. Balance Control Characteristics (1) µPC1892CT -0 -20 Attenuation (dB) -40 Lch→flat Rch→ATT Lch→ATT Rch→flat -60 OFF mode f = 1 kHz VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VEFF = 2.5 V VT = 2.5 V JIS-A filter used -80 -100 0 1 2 3 4 5 Balance Control Voltage (V) Caution (2) µPC1892CT-02 If the control voltage is set to over 5 V, L-channel output level becomes lower. -0 -20 Attenuation (dB) -40 Lch→flat Rch→ATT Lch→ATT Rch→flat -60 OFF mode f = 1 kHz VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VEFF = 2.5 V VT = 2.5 V JIS-A filter used -80 -100 0 1 2 3 4 5 Balance Control Voltage (V) Remark VL+R: L+R volume control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VEFF: Effect control voltage, VBAL: Balance control voltage, VVOL: Volume control voltage, VT: Tone control voltage. 35 µPC1892 3. Tone Control Characteristics 10 5 OFF mode Bass : f = 100 Hz Treble : f = 10 kHz VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VBAL = 2.5 V Gain G (dB) -0 -5 -10 -15 0 1 2 3 4 5 Bass, Treble Control Voltage (V) 4. Tone Frequency Characteristics 15 VC = 4.5 V 10 VC = 4.0 V VC = 3.5 V 5 VC = 3.0 V Gain G (dB) 0 OFF mode VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VBAL = 2.5 V VC = 2.5 V VC = 2.0 V VC = 1.5 V VC = 1.0 V -5 -10 VC = 0.5 V -15 100 1.00 k Frequency f (Hz) 10.0 k Remark VBAL: Balance control voltage, VVOL: Volume control voltage, VC: Bass, Treble control voltage. 36 µPC1892 5. Effect Control Voltage 10 Movie mode 0 Music mode Level attenuation (dB) -10 Simulated mode -20 f = 1 kHz VIN = 1.4 VP-P (=0 dB) VVOL = 5.0 V VL+R = 5.0 V VBAS = 2.5 V VTRE = 2.5 V VBAL = 2.5 V -30 -40 0 1 2 3 4 5 Effect control voltage (V) Remark VVOL: Volume control voltage, VL+R: L+R volume control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage, VBAL: Balance control voltage. INPUT/OUTPUT CHARACTERISTICS, DISTORTION FACTOR f = 1 kHz VVOL = 5.0 V VBAL = 2.5 V VBAS = 2.5 V VTRE = 2.5 V 0.3 3.0 Output voltage 0.2 2.0 Distortion factor 0.1 1.0 0 0.5 1.0 1.5 2.0 2.5 3.0 3.5 Input signal (Vrms) Remark VVOL: Volume control voltage, VBAL: Balance control voltage, VBAS: Bass control voltage, VTRE: Treble control voltage. Output Voltage (Vrms) Distortion factor (%) 37 38 Effect control 10 kΩ RIN 820 kΩ R2 1000 pF C21 C20 0.082 µF 29 28 680 pF C19 + 22 µ F 22 µ F 22 µ F C18 + C17 + C16 510 Ω 23 C15 C14 510 Ω 20 510 Ω 19 510 Ω 18 LIN 6800 pF 0.15 µ F (±1 %) (±1 %) Balance control 10 kΩ Volume control 10 kΩ L+R volume control Bass control 10 kΩ 10 kΩ +5 V 30 27 26 25 24 22 21 Treble control 510 10 kΩ Ω 510 Ω 17 16 CIRCUIT OF EVALUATION BOARD µ PC75L05J VCC µ PC1892CT C13 0.1 µ F C12 0.33 µ F 1 VCC LED R1 1 kΩ VCC 2 3 4 5 6 1 kΩ +C5 7 8 1 kΩ 9 10 11 12 13 14 15 C1 C2 C3 C4 C7 L H C8 0.1 µ F 2200 0.022 0.022 1 µ F pF µF µF L H 6800 pF 0.15 µ F (±1 %) (±1 %) Mode Select Code MS1 (Pin 7) OFF L Music H Movie L Simulated H MS2 (Pin 8) L L H H + C10 4.7 µ F + C11 4.7 µ F + C9 4.7 µ F + C6 4.7 µ F Lout L+Rout Rout REARout µPC1892 MS1 MS2 +5 V µPC1892 PACKAGE DIMENSIONS 30PIN PLASTIC SHRINK DIP (400 mil) 30 16 1 A 15 K I L J H G F D N M C B M R NOTES 1) Each lead centerline is located within 0.17 mm (0.007 inch) of its true position (T.P.) at maximum material condition. 2) ltem "K" to center of leads when formed parallel. ITEM A B C D F G H I J K L M N R MILLIMETERS 28.46 MAX. 1.78 MAX. 1.778 (T.P.) 0.50±0.10 0.85 MIN. 3.2±0.3 0.51 MIN. 4.31 MAX. 5.08 MAX. 10.16 (T.P.) 8.6 0.25 +0.10 –0.05 0.17 0~15 ° INCHES 1.121 MAX. 0.070 MAX. 0.070 (T.P.) 0.020 +0.004 –0.005 0.033 MIN. 0.126±0.012 0.020 MIN. 0.170 MAX. 0.200 MAX. 0.400 (T.P.) 0.339 0.010 +0.004 –0.003 0.007 0~15 ° S30C-70-400B-1 39 µPC1892 RECOMMENDED SOLDERING CONDITIONS The following conditions (see table below) must be met when soldering this product. For more details, refer to our document "SEMICONDUCTOR DEVICE MOUNTING TECHNOLOGY MANUAL" (IEI-1207). Please consult with our sales offices in case other soldering process is used, or in case soldering is done under different conditions. Type of Through Hole Device µPC1892CT : 30-pin plastic shrink DIP (400 mil) µPC1892CT-02 : 30-pin plastic shrink DIP (400 mil) Soldering Process Wave Soldering (For leads only) Partial Heating Method Soldering Conditions Solder temperature: 260 °C or lower. Flow time: 10 seconds or less. Pin temperature: 260 °C or lower. Time: 10 seconds or less. Caution Do not jet molten solder on the surface of package. 40 µPC1892 [MEMO] 41 µPC1892 [MEMO] The application circuits and their parameters are for references only and are not intended for use in actual design-in's. No part of this document may be copied or reproduced in any form or by any means without the prior written consent of NEC Corporation. NEC Corporation assumes no responsibility for any errors which may appear in this document. NEC Corporation does not assume any liability for infringement of patents, copyrights or other intellectual property rights of third parties by or arising from use of a device described herein or any other liability arising from use of such device. No license, either express, implied or otherwise, is granted under any patents, copyrights or other intellectual property rights of NEC Corporation or others. While NEC Corporation has been making continuous effort to enhance the reliability of its semiconductor devices, the possibility of defects cannot be eliminated entirely. To minimize risks of damage or injury to persons or property arising from a defect in an NEC semiconductor device, customer must incorporate sufficient safety measures in its design, such as redundancy, fire-containment, and anti-failure features. NEC devices are classified into the following three quality grades: “Standard“, “Special“, and “Specific“. The Specific quality grade applies only to devices developed based on a customer designated “quality assurance program“ for a specific application. The recommended applications of a device depend on its quality grade, as indicated below. Customers must check the quality grade of each device before using it in a particular application. Standard: Computers, office equipment, communications equipment, test and measurement equipment, audio and visual equipment, home electronic appliances, machine tools, personal electronic equipment and industrial robots Special: Transportation equipment (automobiles, trains, ships, etc.), traffic control systems, anti-disaster systems, anti-crime systems, safety equipment and medical equipment (not specifically designed for life support) Specific: Aircrafts, aerospace equipment, submersible repeaters, nuclear reactor control systems, life support systems or medical equipment for life support, etc. The quality grade of NEC devices in “Standard“ unless otherwise specified in NEC's Data Sheets or Data Books. If customers intend to use NEC devices for applications other than those specified for Standard quality grade, they should contact NEC Sales Representative in advance. Anti-radioactive design is not implemented in this product. M4 94.11 2

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