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| HA12155NT/HA12157NT Audio Signal Processor for Cassette Deck (Dolby B/C-type NR with Recording System) ADE-207-115C (Z) 4th Edition June 1997 Description HA12155NT/HA12157NT is silicon monolithic bipolar IC providing Dolby noise reduction system*, electrical volume system, REC equalizer system and level meter system in one chip. Functions * REC equalizer * Dolby B/C NR * Electronic volume * Level Meter x 2 channel x 2 channel x 2 channel x 2 channel Features * Inductor less REC equalizer is adjustable of its characteristics by external resistor * Rec level is adjustable automatically with electrical volume which is built-in * 3 type of input selection is available (one is by way of electrical volume) * Separate input selection SW and REC/PB SW * Dolby noise reduction with dubbing cassette decks (Unprocessed signal output available from recording out terminals during PB mode) * Log-compressed level meter output is range from 0 V to 5 V (Usable as music search switchable gain of 0 dB and 20 dB respectivily) * Normal-speed/high-speed (Double), normal/metal/chrome fully electronic control switching built-in * NR-ON/OFF, Dolby B/C, MPX ON/OFF fully electronic control switching built-in (Controllable from micro-controller directly) * Reduction of number of pin by transfered serial data to electronic volume control switching and another control switching (Controllable from micro-controller directly) * Low external parts count HA12155NT/HA12157NT * Dolby is a trademark of Dolby Laboratories Licensing Corporation. A license from Dolby Laboratories Licensing Corporation is required for the use of this IC. Ordering Information Operating voltage Type HA12155NT HA12157NT Package DP-64S Dolby Level 300 mVrms REC-OUT Level PB-OUT Level 300 mVrms 580 mVrms 775 mVrms Min 9.5 V 12 V Max 16 V 16 V Rev.4, Jun. 1997, page 2 of 57 Block Diagram GND VRI CNT RPI PBI DATA CLK STB (1) (L) (L) (L) BIAS (L) DGND NRIN Vref M (L) (L) IA OUT (L) PB OUT (L) GND EQ (2) OUT(L) P X REC OUT(L) LM IN(L) LM OUT(L) EQ IN(L) 51 47 38 46 45 44 42 39 50 49 48 41 40 43 NN NC NM HN HC HM 37 36 35 34 33 64 55 52 53 63 62 54 61 60 59 58 57 56 RECT Dolby B/C NR IA + LMA - REC EQ Shift register 6BIT DAC Latch Decoder E VOL SW IA Dolby B/C NR RECT E VOL - LMA + REC EQ BIAS 6BIT DAC EQ-Controller 1 2 3 4 5 6 13 14 15 16 7 8 9 10 11 12 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 FM fQ f/Q GH GL GP HA12155NT/HA12157NT Rev.4, Jun. 1997, page 3 of 57 M P X NRIN PBOUT IA OUT (R) Vref (R) (R) (R) NR C/B MPX VCC VRI CNT RPI REF PBI INJ (R) ON/OFF (R) (R) (R) ON/OFF REC OUT(R) LM IN(R) EQ IN(R) IREF EQ OUT(R) LM OUT(R) HA12155NT/HA12157NT Absolute Maximum Ratings Item Supply voltage Power dissipation*1 Operating temperature Storage temperature Note: 1. Value at Ta 75C Symbol VCC Pd Topr Tstg Ratings 16 770 -30 to +75 -55 to +125 Unit V mW C C Electrical Characteristics (Ta = 25C VCC = 14 V Dolby level 300 mVrms) Item Quiescent current Input amp gain Symbol IQ GVIA RPI GVIA PBI B-type NR Encode Boost B-ENC-2K B-ENC-5K C-type NR Encode Boost C-ENC-1K(1) C-ENC-1K(2) C-ENC-700 Signal handling Signal to noise ratio Total harmonic distortion Crosstalk Vomax S/N THD CT (RL) Min -- 18.5 18.5 2.8 1.7 3.9 18.1 9.8 12.0 60.0 -- -- Typ 29.0 20.0 20.0 4.3 3.2 5.9 19.6 11.8 13.0 63.0 0.08 Max 37.0 21.5 21.5 5.8 4.7 7.9 21.6 13.8 -- -- 0.3 dB dB % dB dB Vin = -20 dB, f = 2 kHz Vin = -20 dB, f = 5 kHz Vin = -20 dB, f = 1 kHz Vin = -60 dB, f = 1 kHz Vin = -30 dB, f = 700 Hz f = 1 kHz, THD = 1%, VCC = 12 V Rg = 5.1 k, CCIR/ARM Vin = 0 dB, f = 1 kHz Vin = 0 dB, f = 1 kHz *1 Unit mA dB Test conditions no signal Vin = 0 dB, f = 1 kHz Notes -85.0 -79.0 dB -80.0 -74.0 -77.0 -71.0 -- -- -- -- 580 775 5.3 1.0 5.3 1.0 670 900 +100 mV 1.0 21.5 -55.0 dB dB V V CT (RPIPBI) -- CT (VRIRPI) -- Control voltage Serial data voltage PB-out level Hi level Lo level Hi level Lo level HA12155 HA12157 PB-offset Channel balance Volume gain Vofs GV GVVR (MAX) GVVR (MIN) VcH VcL VsH VsL Vout 3.5 -0.2 3.5 -0.2 500 665 MPX ON/OFF, NR ON/OFF C-NR/B-NR CLK, DATA, STB mVrms Vin = 0 dB, f = 1 kHz -100 0.0 -1.0 17.5 -- 0.0 19.3 -- no signal Vin = 0 dB, f = 1 kHz Vin = 100 mVrms, f =1 kHz Vin = 3 Vrms, f = 1 kHz Rev.4, Jun. 1997, page 4 of 57 HA12155NT/HA12157NT Electrical Characteristics (Ta = 25C VCC = 14 V Dolby level 300 mVrms) (cont) Item Volume mute Symbol GVVR (MUT) Min -- 11.0 78.0 -- 13.0 13.0 14.5 18.5 29.5 -8.0 57.0 -- Typ -- 12.6 84.0 0.04 15.0 15.0 16.5 20.5 32.0 -7.0 62.0 0.2 Max Unit Test conditions Vin = 3 Vrms, f = 1 kHz f = 1 kHz, THD = 1%, VCC = 12 V Vin = 100 mVrms, f = 1 kHz, A-WTG Vin = 100 mVrms, f = 1 kHz Vin = 77.5 mVrms, f = 500 Hz Vin = 77.5 mVrms, f = 1 kHz Vin = 77.5 mVrms, f = 5 kHz Vin = 77.5 mVrms, f = 10 kHz Vin = 77.5 mVrms, f = 20 kHz dBs dB % f = 1 kHz, THD = 1%, VCC = 12 V Rg = 5.1 k, A-WTG Vin = 77.5 mVrms, f = 1 kHz no signal Vin = 0 dB, f = 1 kHz Vin = 12 dB, f = 1 kHz Vin = -20 dB, f = 1 kHz Vin = -20 dB, f = 1 kHz, -20 dB range no signal no signal, -20 dB range *2 *2 *1 Notes -80.0 dB -- -- 0.3 17.0 17.0 18.5 22.5 34.5 -- -- 0.5 dBs dB % dB Max-input level to volume Vin max (VR) Volume S/N Volume THD Equalizer gain S/N (VR) THD (VR) GV EQ (500) GV EQ (1K) GV EQ (5K) GV EQ (10K) GV EQ (20K) Equalizer maximum input Vin max (EQ) Equalizer S/N Equalizer THD Equalizer offset Level meter output S/N (EQ) THD (EQ) Vofs (EQ) LM (0 dB) LM (12 dB) Level meter output LM (-20 dB)1 LM (-20 dB)2 Level meter offset LMofs 1 LMofs 2 -400 0.0 2.60 3.60 0.80 2.55 -- -- 2.85 3.90 1.10 3.0 150 200 +400 mV 3.10 4.20 1.40 3.15 300 350 V V V V mV Notes: 1. HA12155 VCC = 9.5 V, HA12157 VCC = 12 V 2. 0 dB = PB-OUT level Rev.4, Jun. 1997, page 5 of 57 DC VM 2 ON SW14 L R SW15 PB REC EQ SW16 OFF Test Circuit Mode controller AC VM 2 PB LM REC EQ R72 16 k SW12 EQ SW4 SW8 TP3 SW10 R19 10 k C21 C20 + + 0.47 PB RP R25 10 k TP4 OFF SW25 C29 C27 C26 C25 L R22 7.5 k Rev.4, Jun. 1997, page 6 of 57 R28 10 k R21 20 k C24 + + VR R20 R71 C22 100 k 51 k 1 C23 0.1 4.7 Degital ON GND 2200p 2200p 3 C60 C61 C62 R67 5.1 k C1 R27 R26 2.4 k 5.6 k R24 22 k R23 560 R66 5.1 k C30 + 2.2 C28 10p 10p 10p HA12155NT/HA12157NT R4 10 k R5 10k R6 10 k 0.47 C3 2200p 0.1 0.1 C33 2.2 C2 R29 + + 1 + 0.47 18 k + 0.47 64 52 38 NC NM HN 63 51 37 50 49 48 47 46 45 44 43 42 41 40 39 62 61 60 59 58 57 56 55 54 53 36 35 34 HC 33 HM DATA CLK STB GND VRI (1) (L) CNT RPI (L) (L) BIAS PBI DGND IA OUT NRIN V REF PBOUT SS1 SS2 CCR HLS REC LM LM LM LLS NN EQ GND EQ (L) (L) (L) (L) (L) (L) DET(L) DET(L) OUT(L) IN(L) DET(L) OUT(L) IN(L) (2) OUT(L) (L) (L) HA12155/7 NT (REC 1 CHIP) INJ IA OUT NRIN V REF PBOUT SS1 SS2 CCR HLS REC LM LM LM EQ EQ LLS (R) (R) (R) (R) (R) (R) DET(R) DET(R) OUT(R) IN(R) DET(R) OUT(R) IN(R) IREF OUT(R) FM (R) FQ DP-64S F/Q GH GL GP VRI MPX NR ON/OFFC/B ON/OFF V CC (R) CNT RPI (R) (R) REF PBI (R) 1 17 C12 2200p 0.1 0.1 2.2 2 11 19 C14 C16 0.1 C17 1 R16 100 k SW9 R15 7.5 k R18 10 k + C15 + 3 + 4 R8 1.2 k OFF 5 R9 R10 2.4 k 5.6 k R11 22 k C13 C18 + R17 24 k 0.47 R14 20 k R13 560 4.7 6 22 7 8 9 10 13 14 25 12 15 16 18 20 21 24 26 23 + C19 27 R30 R36 R42 R48 R54 28 29 R31 R37 R43 R49 R55 30 R32 R38 R44 R50 R56 R33 R39 R45 R51 R57 31 R34 R40 R46 R52 R58 32 R35 R41 R47 R53 R59 R1 R2 R3 22 k 22 k 22 k R7 10 k ON TP1 SW7 R12 10 k TP2 SW24 C11 C9 C10 + 2200 p 2200 p 2.2 C4 + C5 + C6 + C7 + C8 0.47 1 0.47 1 0.47 SW18 SW19 SW20 R68 5.1 k R69 5.1 k OFF ON b c ON OFF C32 100 SW21 SW22 SW23 + S2 S3 S2 S3 S2 S3 R70 51k R75 16 k R60 R61 R62 R63 R64 R65 51 k 33 k 33 k 33 k SW3 L VR RP PB AC VM 3 EQ 100k 51 k SW11 REC PB R R L SW17 LM EQ REC PB SW13 ON EQ OFF SW1 Audio SG 5V AC VM 1 DC Source 1 DC Source 2 DC Source 3 AC VM 4 Distortion analyzer Oscilloscope Noise meter Noise meter with CCIR/ARM filter and A-WTG filter 14 V Notes 1: Registor tolerance are 1 % 2: Capacitor tolerance are 1 % 3: Unit R: C:F CN1 PBOUT (L) STB 1 PBI (L) RECOUT (L) TP3 TP4 EQOUT (L) R72 16 k EQIN (L) LMOUT (L) CLK 2 DATA 3 RPI (L) DGND 4 MPX ON/OFF 5 C/B R25 10 k R22 7.5 k R19 10 k C20 + 0.47 39 38 37 NC 6 VRI (L) 7 C30 + 2.2 C28 C29 2200 p 2200 p NR ON/OFF VCC2 (+5 V) R66 5.1 k Degital GND 8 R28 10 k C27 2200 p C62 10p C26 0.1 0.1 + 2.2 + 44 GND EQ NN (2) OUT (L) R67 5.1 k C25 + 0.47 42 41 40 Example of Split Supply Circuit C60 10p R4 10 k R27 R26 2.4 k 5.6 k 54 Vref PBOUT SS1 (L) (L) (L) SS2 (L) CCR HLS LLS REC LM LM LM EQ (L) DET (L) DET (L) OUT (L) IN (L) DET (L) OUT (L) IN (L) R5 10 k R24 22 k 51 50 49 48 47 46 45 43 R23 560 53 52 C61 10p R6 10 k 36 NM C3 R20 R71 C22 100 k 51 k R21 1 20 k C23 C24 0.1 C21 35 HN + 64 BIAS PBI DGND IAOUT NRIN (L) (L) (L) 63 62 61 C33 C2 R29 C1 18 k + + + 0.47 1 0.47 0.47 60 59 58 57 56 55 34 HC 33 HM DATA CLK STB GND (1) VRI (L) CNT (L) RPI (L) HA12155/7 (REC 1 CHIP) REF PBI (R) INJ IAOUT NRIN (R) (R) Vref PBOUT SS1 (R) (R) (R) SS2 (R) CCR HLS LLS REC LM LM LM EQ (R) DET (R) DET (R)OUT (R) IN (R) DET (R)OUT (R) IN (R) DP-64S EQ IREF OUT (R) FM FQ FQ GH GL GP NR MPX ON/OFF C/B ON/OFF VCC VRI (R) CNT (R) PRI (R) 1 1 0.47 *1 R7 10 k 2200 p 2200 p 2 R8 C16 0.1 C17 1 R16 100 k + C9 C10 R14 20 k + C11 2.2 R12 10 k TP2 R75 16 k TP1 EQIN (R) 2200 p 3 R9 R10 2.4 k 5.6 k C12 0.1 0.1 C13 C14 R11 22 k R13 560 C15 + 2.2 C18 + 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 C4 + C5 + C6 + C7 + C8 + R1 22 k R69 5.1 k R2 22 k R3 22 k 0.47 1 0.47 0.47 R17 26 27 28 29 30 31 32 C19 R30 R31 R32 R33 R34 R35 + 4.7 R36 R37 R38 R39 R40 R41 R42 R48 R15 7.5 k R70 51 k R54 R60 R43 R49 R18 10 k R55 R61 100 k 51 k R44 R45 R50 R51 R56 R57 R62 R63 51 k 33 k EQOUT (R) R46 R52 R58 R64 33 k R47 R53 R59 R65 33 k R68 5.1 k VRI (R) RPI (R) RBI (R) CN2 RECOUT (R) LMOUT (R) GND 1 VEE 2 + C34 100 + C32 100 PBOUT (R) VCC1 3 Note 1: The pin 10 can connect to VCC 1 through R8. The value of external resistor R8 is obtained by using following equations. R8 = VINJ - VEE - 0.7 (k ) 3.6 HA12155NT/HA12157NT Rev.4, Jun. 1997, page 7 of 57 GND V CC (+5 V) + SW1 SW2 SW3 C4 100 R4 22 K JP1 N13 IC8 N1 IC6 R 17 22 k R5 22 K R3 1M 1 NR*ON/OFF Mode Controller R2 22 k + C 1 2.2 TRIGGER R1 22 k 6 C/B JP2 JP3 Rev.4, Jun. 1997, page 8 of 57 PR Q DQ CLR PR Q DQ CLR Q Q CLR D1 IC2 D2 IC2 N5 IC8 N2 IC8 N3 IC6 N4 IC8 MCLK CLR QA QB Q C QD D9 IC9 5 MPX*ON/OFF HA12155NT/HA12157NT SW9 D3 IC3 TRIGGER IC 1 PR Q DQ CLR X'tal OSC N11 IC8 N12 IC8 R 22 D8 IC3 1M R4 510 D4 IC5 Q DQ CLR CLR Q A Q B QC Q D 1 N6 IC6 Q DQ CLR STB D6 IC5 C2 X'tal C 3 10 p 1 MHz 120 p 62.5 kHz SW10 125 kHz 250 kHz 500 kHz D5 IC5 R7 22 k R 8 R 9 R 10 R 11 R 12 R 13 R 14 22 k 22 k 22 k 22 k 22 k 22 k 22 k Q DQ CLR 4 8 N7 IC6 N8 IC7 N9 IC7 GND VCC (+5 V) 2 CLK SW8 SW7 SW6 SW5 SW4 SW3 SW2 SW1 ABCDEFG N10 IC7 Type D7 H CLK CLK SHIFT LOAD INHIBIT QH IC4 3 DATA Notes 1: HC type IC which operate eqaully is also applicable instead of IC1-IC9. 2: As for IC1-IC9, input pins which are not used should be pulled up with resistor of 22 k . Parts No. IC1 IC2 IC3 IC4 IC5 IC6 IC7 IC8 IC9 HD74HC221 HD74HC74 HD74HC393 HD74HC165 HD74HC175 HD74HC00 HD74HC00 HD74HC04 HD74HC74 3: As for IC1-IC9, required to put 0.1 F-capacitor between near GND pin and Voltage source pin for bypass. 4: Unit R : , C : F HA12155NT/HA12157NT Pin Description (VCC = 14 V, Ta = 25C, No signal, the value in the table show typical value) Pin No. DP-64S 7 58 Terminal name RPI Zin 100 k DC voltage VCC/2 Equivalent circuit Description Recording input 9 56 21 44 24 41 5 60 4 8 12 53 PBI Play back input LM IN HA12155 ---75 k HA12157 ---100 k Level meter input EQ IN 100 k Equalyzer input VRI 100 k VCC/2 +0.7 V VCC VCC/2 VCC/2 -- -- Volume input VCC REF NR IN -- -- -- Power supply Ripple filter NR processor input 15 50 SS 1 -- VCC/2 Spectral skewing amp input Rev.4, Jun. 1997, page 9 of 57 HA12155NT/HA12157NT Pin Description (VCC = 14 V, Ta = 25C, No signal, the value in the table show typical value) (cont) Pin No. DP-64S 17 48 Terminal name CCR Zin -- DC voltage VCC/2 Equivalent circuit Description Current controled resistor output 11 54 IA OUT -- VCC/2 VCC Input amp output GND 13 52 14 51 16 49 20 45 26 39 VREF Reference voltage buffer output PB OUT Play back (Decode) output SS 2 Spectral skewing amp. output REC OUT Recording (Encode) output EQ OUT Equalyzer output Rev.4, Jun. 1997, page 10 of 57 HA12155NT/HA12157NT Pin Description (VCC = 14 V, Ta = 25C, No signal, the value in the table show typical value) (cont) Pin No. DP-64S 18 47 Terminal name HLS DET Zin -- DC voltage 2.3 V Equivalent circuit Description Time constant pin for rectifier 19 46 57 LLS DET BIAS -- 0.28 V Dolby NR Reference current input GND 25 IREF -- 1.2 V EQ Reference current input 27 28 29 30 31 32 FM fQ f/Q GH GL GP EQ Parameter current input Rev.4, Jun. 1997, page 11 of 57 HA12155NT/HA12157NT Pin Description (VCC = 14 V, Ta = 25C, No signal, the value in the table show typical value) (cont) Pin No. DP-64S 33 Terminal name HM Zin -- DC voltage -- Equivalent circuit Description EQ Parameter selector GND 34 35 36 37 38 6 59 HC HN NM NC NN CNT 5.2 k VCC/21.5 V to VCC/2 VCC / 2 DAC output Volume control input DAC out 22 43 LM OUT LMD -- 0.2 V Time constant Pin for level meter GND LMD 23 42 LM OUT -- 0.2 V Level meter output Rev.4, Jun. 1997, page 12 of 57 HA12155NT/HA12157NT Pin Description (VCC = 14 V, Ta = 25C, No signal, the value in the table show typical value) (cont) Pin No. DP-64S 1 Terminal name NR ON/OFF Zin 100 k DC voltage -- Equivalent circuit Description Mode control input D - GND GND 2 3 62 63 64 10 55 40 61 C/B MPX ON/OFF STB CLK DATA INJ D-GND GND -- -- -- 0.7 V 0.0 V 0.0 V -- -- -- Injection current input 2 for I L Digital (Logic) ground Ground Application Note Power Supply Range HA12155NT/HA12157NT are designed to operate on either single supply or split supply. The operating range of the supply voltage is shown in table 1. Table 1 Type No. HA12155NT HA12157NT Supply Voltage Single supply 9.5 V to 16 V 12 V to 16 V Split supply 6 V to 8 V 6 V to 8 V The lower limit of supply voltage depends on the line output reference level. Rev.4, Jun. 1997, page 13 of 57 HA12155NT/HA12157NT The minimum value of the headroom margin is specified as 12 dB by Dolby Laboratories. HA12155 series are provided with two line output level, which will permit an optimum headroom margin for power supply conditions. Reference Voltage For the single supply operation these devices provide the reference voltage of half the supply voltage that is the signal grounds. As the peculiarity of these devices, the capacitor for the ripple filter is very small about 1/100 compared with their usual value. The Reference voltage are provided for the left channel and the right channel separately. The block diagram is shown as figure 1. VCC + - 52 L channel reference 8 + 1 F - + R channel reference 13 Figure 1 The Block Diagram of Reference Voltage Supply Operating Mode Control HA12155NT/HA12157NT provides fully electronic switching circuits. NR-ON/OFF, C/B, and MPX ON/OFF switches are controlled by parallel data (DC voltage) and other switches are controlled by serial data. Rev.4, Jun. 1997, page 14 of 57 HA12155NT/HA12157NT Table 2 Pin No. 1, 2, 3 62, 63, 64 Threshold Voltage (VTH) Lo -0.2 to 1.0 -0.2 to 1.0 Hi 3.5 to 5.3 3.5 to 5.3 Unit V V Notes: 1. Voltages shown above are determined by internal circuits of LSI when take pin 55 (DGND pin) as reference pin. On split supply use, same VTH can be offered by connecting DGND pin to GND pin. This means that it can be controlled directly by micro processor. 2. Each pins are on pulled down with 100 k internal resistor. Therefore, it will be low-level when each pins ar open. 3. Note on serial data inputting (a) The clock frequency on CLK must be less than 500 kHz. (b) Over shoot level and under shoot level of input signal must be the value shown below. (c) The serial input pins (pins 62, 63, and 64) are extremely sensitive to undershoot, overshoot, ringing, and noise. This can result in malfunctions due to problems with the wiring pattern. We recommend attaching capacitors in parallel with the serial input pins to ameliorate this problem. Figure 2-b shows an example of this circuit appropriate when the clock frequency is 500 kHz. The value of the capacitor should be set in accordance with the clock frequency actually used. 4. NR Mode Switching In actual use, pop noises may accompany NR on/off switching in C mode. To avoid these noises, use the following sequences to turn NR on and off. From C mode NR off to C mode NR on: (C mode, NR off) (B mode, NR off) (B mode, NR on) (C mode, NR on). From C mode NR on to C mode NR off: (C mode, NR on) (B mode, NR on) (B mode, NR off) (C mode, NR off). Table 3 Pin No. 1 2 3 Switching Truth Table Lo NR-OFF B-NR MPX-ON Hi NR-ON C-NR MPX-OFF Notes: 1. Low level will be offered when each pins are open. 2. Please refer to next term as for the serial data for formatting. When connecting microcomputer or Logic-IC with HA12155NT/HA12157NT directly, there is apprehension of rash-current under some transition timming of raising voltage or falling voltage at VCC ON/OFF. For this countermeasure, connect 10 k to 20 k resistor with each pins. It is shown in test circuit. Rev.4, Jun. 1997, page 15 of 57 HA12155NT/HA12157NT under 5.3 V 0 within -0.2 V Figure 2 Input Level Serial Data Formatting 8 bit shift register is employed. CLK and DATA are stored during STB being high and data is ratched when STB goes high to low. The clock frequency on CLK must be less than 500 kHz. 5V 0V 5V DATA 0V 5V STB 0V CLK 0 1 2 3 4 5 6 7 latch of data Figure 3 Serial Data Timming Chart Rev.4, Jun. 1997, page 16 of 57 HA12155NT/HA12157NT Table 4 Serial Data Formatting Volume register H L TS1 TS2 H L H TAPE IV TAPE II Bit Control No. register 0 TAPE SELECT 1 DAC0 L TAPE I TAPE I bit No. 5 L L L L 4 L L L L gain 3210 L L L L increase LLLH LLHL LLHH HHHHLH H H H H H L decrese H H H H H H mute 1 TAPE SELECT 2 H L DAC1 *mute is implemented when all bits are high. 2 TAPE SPEED H High (double) speed selection DAC2 L Normal speed selection DAC3 3 METER H Meter sensitivity 20 dB up Meter sensitivity normal SENSITIVITY L 4 INPUT SELECT 1 H L DAC4 IS1 IS2 H L H PB I RP I L VR I VR I 5 INPUT SELECT 2 H L H PB mode selection L REC mode selection DAC 5 6 REC/PB R/L SELECT H Rch register selection L REGISTER SELECT L Lch register selection Volume register selection 7 REGISTER SELECT H Control register selection Note: TAPE I: Normal tape, TAPE II: Chrome tape, TAPE IV: Metal tape Rev.4, Jun. 1997, page 17 of 57 HA12155NT/HA12157NT Input Block Diagram and Level Diagram -3 dB IA OUT RPI PBI 43 mVrms (-25.2 dBs) Input Amp MPX Filter NR lN PB - OUT HA12155 580 mVrms (-2.5 dBs) HA12157 775 mVrms (0 dBs) 43 mVrms (-25.2 dBs) 426 mVrms (-5.2 dBs) MPX ON MPX OFF - 3 dB 300 mVrms (-8.2 dBs) VRI Electrical VR MA NR circuit 47 mVrms (-24.3 dBs) b) REC mode The each level shown above is typical value when offering Dolby level to test point pin (NR IN) with the gain of electrical volume is under the condition of max. IA OUT RPI PBI 30 mVrms (-28.2 dBs) MPX Filter NR lN PB - OUT HA12155 580 mVrms (-2.5 dBs) 30 mVrms (-28.2 dBs) Input Amp 300 mVrms (-8.2 dBs) HA12157 775 mVrms (0 dBs) VRI Electrical VR MA NR circuit 33 mVrms (-27.4 dBs) NR circuit a) PB mode The each level shown above is typical value when offering Dolby level to test point pin (IA OUT) with the gain of electrical volume is under the condition of max. Figure 4 Input Block Diagram Rev.4, Jun. 1997, page 18 of 57 HA12155NT/HA12157NT MPX ON/OFF Switch MPX-OFF mode means that signal from input amp doesn't go through the MPX filter, but signal goes through the SS circuit after being attenuated 3 dB by internal resistor. Refer to figure 5. For not cause any level difference between MPX-ON mode and MPX-OFF mode, it is requested to use MPX-filter which has definitely 3 dB attenuated. MPX-OFF mode offer totally flat frequency response and no bias-trap effect. And when applying other usage except figure 5, take consideration to give bias voltage to NR-IN terminal by resistor or so on because internal of NR-IN terminal hsa no bias resistor. 5.6 k MPX 2.4 k IA OUT NR IN VREF Vref + INPUT amp - MPX ON NR PROCESSER + - MPX OFF 3 dB ATT. Vref Figure 5 MPX ON/OFF Switch Block Diagram Application as for the Dubbing Cassette Deck HA12155NT/HA12157NT series has unprocessor signal from recording out terminals during plyaback mode. So, it is simply applied for dubbing cassette decks. And HA12155NT/HA12157NT has three input terminal. So, it is applicable to switch the signal from PBEQ as shown below. Rev.4, Jun. 1997, page 19 of 57 HA12155NT/HA12157NT A deck B deck PB EQ Compensation of low frequency region RPI PBI REC OUT EQ IN REC IN VRI HA12155 / 7 EQ OUT PB OUT REC PB PB EQ Figure 6 Application for Dubbing Deck Injector Current HA12155NT/HA12157NT has logic circuit which is fabricated by I L into IC. To operate this circuit, it is required enough injector current. Injector current goes into from the INJ pin (pin 10) and external resistor is required to connect to this pin for adequate current. The value of external resistor is obtained by using following equations. And put them with 10% tolerance value which is calculated. VINJ can allow to connect to VCC shown below. Under the condition of high temperature, the mis-operation of logic is caused by large injector current. Also, under the condition of low temperature, the stop of logic is caused by small injector current. Therefore, pay attention to have good stability of VINJ. R INJ = R INJ = VINJ - 0.7 3.6 VINJ + VEE - 0.7 3.6 [k] ---- Single supply 2 [k] ---- Split supply RINJ 10 3.6 mA VINJ HA12155 / 7 40 61 VINJ VEE a) Single supply use RINJ 10 3.6 mA HA12155 / 7 40 61 b) Split supply use Figure 7 Injector Current Application Rev.4, Jun. 1997, page 20 of 57 HA12155NT/HA12157NT Gain Control of Electronic Volume HA12155NT/HA12157NT is designed in order to change the gain by 6 bit DAC fabricated into IC. To reduce the click noise when changing volume gain instantaneously, required to connect the capacitor (CR time constant) to CNT pin (pin 6,59). These terminals are also be used as output pin of DAC. Therefore, by forcing voltage or current to these terminals, it is applicable to control volume gain directly. But, voltage forced to these terminals must be from VCC/2 -2 V to VCC/2 (for split supply use, -2 V to 0 V) in this case. In case of forcing the current these pins, voltage must be the value mentioned above even it is 20% distributed of internal resistor (5.2 k) of CNT pin. And, these case, change of a gain depending on a temperature gets large. The Tolerances of External Components for Dolby NR-Block For adequate Dolby NR tracking response, take external components shown below. For smooth capacitors of C13, C14, C25 and C26, please employ a few object of the leak, though you can be useful for an electrolytic capacitor. C28 2200 p 5% R29 18 k 2% 57 BIAS 51 R24 22 k 2% C29 2200 p 5% R23 560 2% 50 SS1 (L) 49 SS2 (L) C27 C26 2200 p 0.1 5% 10% 48 47 46 CCR (L) HLS DET(L) LLS DET(L) C25 0.1 10% PB OUT (L) HA12155/7 (REC 1 Chip) PB OUT (R) 14 R11 22 k 2% SS1 (R) 15 SS2 (R) 16 R13 560 2% C10 2200 p 5% CCR (R) 17 HLS DET(R) 18 C12 2200 p 5% LLS DET(R) 19 C13 0.1 10% C14 0.1 10% Unit R : C:F C9 2200 p 5% Figure 8 Tolerances of External Components Level Meter The coupling capacitor of LMIN pin (21 pin and 44 pin). For these capacitors please employ a small object of the leak. Rev.4, Jun. 1997, page 21 of 57 HA12155NT/HA12157NT The Application of Equalizer Frequency Response EQ IN + OP1 _ R1 R3 F/Q GP + Gm1 _ _ + OP2 _ R5 R4 R2 + OP6 _ Gm2 + C1 _ OP5 + R6 R7 + Gm3 _ C2 R10 FM + Gm4 _ C3 _ + _ OP7 GL + OP3 _ _ R9 OP4 + EQ OUT Gm5 + _ GH R8 Gm6 + Figure 9 REC Equalizer Block Diagram Transfer Function: C2 C3 Gm6 + S R 4 R 10 R 8 R 10 1 Gm4 Gm5 S Vout R 2 + R 3 Gm3 = + Gm1 Gm5 C3 R4 R 4 C1 C2 2 R7 C2 Vin R2 R9 R6 + R7 1 + 1+ S S+ S Gm 4 R 5 R 6 + R 7 Gm3 R 5 Gm 2 Gm3 -10 R FM R GH S 1 + 6.67 x10 - 3.0 x 10 10 R FQ S R GL 4.16 R + RGP = - 10 -11 -20 2 R REF GL 1 + 4.5 x10 R FQ S + 2.5 x 10 R FQ R F / Q S 1 + 6.67 x 10 R FM S *RREF-----25 pin bias resistance Rev.4, Jun. 1997, page 22 of 57 HA12155NT/HA12157NT Gain g1 3dB BW g2 g3 f1 f2 f3 f Figure 10 REC Equalizer Frequency Response gl = g2 = g3 = f1 = f2 = f3 = BW = Q= 4.16 (6.67 x R GP + R GH ) R REF 4.16 x R GL R REF 4.16 x R GH R REF 1 2 x 6.67 x10 -10 x R FM 2 x 6.67 x10 -10 x R FM x R GH 0.3 1 2 2.25 x10 -21 x R x R FQ F/Q 4 x 2.78 x 10-10 x R F / Q f3 BW = 3.51 x RF/ Q RF/ Q 1 R GL Rev.4, Jun. 1997, page 23 of 57 HA12155NT/HA12157NT Quiescent Current vs. Supply Voltage 35 Quiescent current I Q (mA) 30 REC - C REC - B REC - OFF PB - C PB - B PB - OFF REC : VRI in (DAC Step 0) LM : Normal PB : PBI in (DAC Step 0) LM : Normal 14 16 18 25 8 10 12 Supply voltage Vcc (V) Rev.4, Jun. 1997, page 24 of 57 HA12155NT/HA12157NT Encode Boost vs. Frequency (HA12155) 12 NR-B RPI in RECOUT out 10 : Vin = - 0 dB : Vin = - 10 dB : Vin = - 20 dB : Vin = - 30 dB : Vin = - 40 dB 16 V 14 V 8 Encode Boost (dB) 6 9V 4 2 0 100 200 500 1k 2k 5k 10 k 20 k 50 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 25 of 57 HA12155NT/HA12157NT Encode Boost vs. Frequency (HA12155) 25 NR-C RPI in RECOUT out 20 : Vin = 0 dB : Vin = - 20 dB : Vin = - 30 dB : Vin = - 40 dB : Vin = - 60 dB 16 V 10 14 V 9V 15 Encode Boost (dB) 5 0 -5 -10 100 200 500 1k 2k 5k 10 k 20 k 50 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 26 of 57 HA12155NT/HA12157NT 12 Encode Boost vs. Frequency (HA12157) NR-B RPI in RECOUT out 10 : Vin = 0 dB : Vin = - 10 dB : Vin = - 20 dB : Vin = - 30 dB : Vin = - 40 dB Encode Boost (dB) 8 16 V 14 V 6 11 V 4 2 0 100 200 500 1k 2k 5k 10 k 20 k 50 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 27 of 57 HA12155NT/HA12157NT Encode Boost vs. Frequency (HA12157) 25 NR-C RPI in RECOUT out 20 : Vin = - 0 dB : Vin = - 20 dB : Vin = - 30 dB : Vin = - 40 dB : Vin = - 60 dB 15 16 V 14 V 11 V Encode Boost (dB) 10 5 0 -5 - 10 100 200 500 1k 2k 5k 10 k 20 k 50 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 28 of 57 HA12155NT/HA12157NT Output Gain vs. Frequency (HA12155) 26 PB OUT 22 Output gain Gv (dB) 18 REC OUT 14 10 (NR - OFF, RPI) Vcc = 14 V REC mode 6 10 30 60 100 300 600 1k 3k 6 k 10 k 30 k 60 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 29 of 57 HA12155NT/HA12157NT Output Gain vs. Frequency (HA12155) 28 PB OUT 24 Output gain Gv (dB) 20 REC OUT 16 12 PB mode (NR - OFF, RPI) Vcc = 14 V 8 10 30 60 100 300 600 1 k Frequency (Hz) 3k 6 k 10 k 30 k 60 k 100 k Rev.4, Jun. 1997, page 30 of 57 HA12155NT/HA12157NT Output Gain vs. Frequency (HA12157) 28 PB OUT 24 Output gain Gv (dB) 20 REC OUT 16 12 (NR - OFF, RPI) Vcc = 14 V REC mode 8 10 30 60 100 300 600 1 k 3k 6 k 10 k 30 k 60 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 31 of 57 HA12155NT/HA12157NT Output Gain vs. Frequency (HA12157) 30 PB OUT 26 Out put gain Gv (dB) 22 REC OUT 18 14 PB mode (NR - OFF, PBI) Vcc = 14 V 10 10 30 60 100 300 600 1 k Frequency (Hz) 3k 6 k 10 k 30 k 60 k 100 k Rev.4, Jun. 1997, page 32 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12155) 10 RPI in RECOUT out REC mode f = 100 Hz V CC = 14 V 3.0 0 dB = 300 mVrms 1.0 NR-C 0.3 Total harmonic distortin T.H.D. (%) 0.1 NR-B 0.03 NR-OFF -10 -5 0 5 10 15 0.01 -15 Output level Vout (dB) Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12155) 10 RPI in RECOUT out REC mode f = 1 kHz V CC = 14 V 3.0 0 dB = 300 mVrms 1.0 0.3 NR-C 0.1 NR-B 0.03 NR-OFF -10 -5 0 5 10 15 0.01 -15 Output level Vout (dB) Rev.4, Jun. 1997, page 33 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12155) 10 RPI in RECOUT out REC mode f = 10 kHz V CC = 14 V 3.0 0 dB = 300 mVrms 1.0 Total harmonic distortion T.H.D. (%) 0.3 NR-C 0.1 NR-B 0.03 NR-OFF 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12155) 10 PBI in PBOUT out PB mode f = 100 Hz V CC = 14 V 3.0 0 dB = 580 mVrms 1.0 NR-C 0.3 NR-OFF 0.1 0.03 NR-B 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Rev.4, Jun. 1997, page 34 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12155) 10 PBI in PBOUT out PB mode f = 1 kHz V CC = 14 V 3.0 0 dB = 580 mVrms 1.0 Total harmonic distortion T.H.D. (%) 0.3 NR-C 0.1 NR-OFF 0.03 NR-B 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12155) 10 PBI in PBOUT out PB mode f = 10 kHz V CC = 14 V 3.0 0 dB = 580 mVrms 1.0 0.3 NR-C 0.1 NR-OFF 0.03 NR-B 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Rev.4, Jun. 1997, page 35 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12157) 10 RPI in RECOUT out REC mode f = 100 Hz V CC = 14 V 3.0 Total harmonic distortion T.H.D. (%) 1.0 NR-C 0.3 NR-B 0.1 0.03 NR-OFF -10 -5 0 5 10 15 Output level Vout (dB) 0.01 -15 Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12157) 10 RPI in RECOUT out REC mode f = 1 kHz VCC = 14 V 3.0 1.0 0.3 NR-C 0.1 0.03 NR-B NR-OFF -10 -5 0 5 10 15 Output level Vout (dB) 0.01 -15 Rev.4, Jun. 1997, page 36 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12157) 10 RPI in RECOUT out REC mode f = 10 kHz V CC = 14 V 3.0 Total harmonic distortion T.H.D. (%) 1.0 0.3 NR-C 0.1 NR-B 0.03 NR-OFF 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12157) 10 RBI in RBOUT out PB mode f = 100 Hz V CC = 14 V 3.0 1.0 NR-C 0.3 0.1 NR-OFF 0.03 NR-B -10 -5 0 5 10 15 Output level Vout (dB) 0.01 -15 Rev.4, Jun. 1997, page 37 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. Output Level (HA12157) 10 PBI in PBOUT out REC mode f = 10 kHz V CC = 14 V 3.0 Total harmonic distortion T.H.D. (%) 1.0 0.3 NR-C 0.1 0.03 NR-B 0.01 -15 NR-OFF -10 -5 0 5 10 15 Output level Vout (dB) Total harmonic distortion T.H.D. (%) Total Harmonic Distortion vs. Output Level (HA12157) 10 PBI in PBOUT out PB mode f = 10 kHz V CC = 14 V 3.0 1.0 0.3 NR-C 0.1 NR-OFF 0.03 NR-B 0.01 -15 -10 -5 0 5 10 15 Output level Vout (dB) Rev.4, Jun. 1997, page 38 of 57 HA12155NT/HA12157NT Max. Output Level vs. Supply Voltage (HA12155) 20 Max. output level Vo max (dB) 15 OFF B C 10 5 T.H.D. = 1% 0 dB = 300 mVrms f = 1 kHz REC mode RPI in RECOUT out 0 8 9 10 11 12 13 14 Supply voltage VCC (V) 15 16 Max. Output Level vs. Supply Voltage (HA12155) 20 Max. output level Vo max (dB) 15 10 5 T.H.D. = 1% 0 dB = 580 mVrms f = 1 kHz PB mode PBI in PBOUT out 0 8 9 10 11 12 13 14 Supply voltage VCC (V) 15 16 Rev.4, Jun. 1997, page 39 of 57 HA12155NT/HA12157NT Max. Output Level vs. Supply Voltage (HA12157) 20 Max. output level Vo max (dB) 15 10 OFF B C 5 T.H.D. = 1% 0 dB = 300 mVrms f = 1 kHz REC mode RPI in RECOUT out 0 9 10 11 12 13 15 16 Supply voltage V CC (V) Max. Output Level vs. Supply Voltage (HA12157) 20 Max. output level Vo max (dB) 15 10 OFF B C 5 T.H.D. = 1% 0 dB = 775 mVrms f = 1 kHz PB mode PBI in PBOUT out 0 10 11 12 13 14 15 16 Supply voltage V CC (V) Rev.4, Jun. 1997, page 40 of 57 HA12155NT/HA12157NT Signal-to-Noise Ratio vs. Supply Voltage (HA12155) PB-C 90 PB-B REC-OFF RPI REC-OFF VRI Signal-to-noise ratio S/N (dB) 80 PB-OFF REC-B RPI REC-B VRI 70 REC-C RPI REC-C VRI 60 E Vol : DAC Step No.18 Vin = 100 mVrms CCIR/ARM 50 9 10 11 12 13 14 15 16 Supply voltage Vcc (V) Rev.4, Jun. 1997, page 41 of 57 HA12155NT/HA12157NT Signal-to-Noise Ratio vs. Supply Voltage (HA12157) 90 PB-C PB-B REC-OFF RPI REC-OFF VRI Signal-to-noise ratio S/N (dB) 80 RB-OFF PB-B RPI REC-B VRI 70 REC-C RPI REC-C VRI 60 VRI : DAC Step No.18 Vin = 100 mVrms CCIR/ARM 50 10 11 12 13 14 15 16 Supply voltage VCC (V) Crosstalk vs. Frequency (R -20 L) -40 L) (dB) REC mode RPI in RECOUT out Vin = +6 dB VCC = 14 V -60 C -80 B -100 OFF 100 1k Frequency (Hz) 10 k 100 k Crosstalk (R -120 10 Rev.4, Jun. 1997, page 42 of 57 HA12155NT/HA12157NT Crosstalk vs. Frequency (R -20 L) -40 L) (dB) PB mode RPI in PBOUT out Vin = +6 dB VCC = 14 V -60 C -80 OFF -100 B -120 10 Crosstalk (R 100 1k 10 k 100 k Frequency (Hz) Crosstalk vs. Frequency 0 VCC = 14 V -20 Crosstalk (dB) -40 RPI -60 PBI -80 RPI -100 10 VRI 30 60 100 300 600 1 k 3 k 6 k 10 k 30 k 60 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 43 of 57 HA12155NT/HA12157NT Crosstalk vs. Frequency 0 VCC = 14 V -20 Crosstalk (dB) -40 -60 PBI RPI PBI VRI -80 -100 10 30 60 100 300 600 1 k 3 k 6 k 10 k 30 k 60 k 100 k Frequency (Hz) Crosstalk vs. Frequency 0 VCC = 14 V -20 Crosstalk (dB) -40 -60 VRI RPI -80 VRI -100 10 30 60 100 300 600 1 k 3 k 6 k 10 k PBI 30 k 60 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 44 of 57 HA12155NT/HA12157NT Ripple Rejection Ratio vs. Frequency (REC mode) 0 V CC = 14 V RECOUT out -10 Ripple rejection ratio R.R.R. (dB) -20 C -30 B -40 OFF -50 10 50 100 500 1 k Frequency (Hz) 5 k 10 k 50 k 100 k Ripple Rejection Ratio vs. Frequency (PB mode) -10 Ripple rejection ratio R.R.R. (dB) -20 -30 OFF -40 B C -50 -60 10 V CC = 14 V PBOUT out 50 100 500 1 k Frequency (Hz) 5 k 10 k 50 k 100 k Rev.4, Jun. 1997, page 45 of 57 HA12155NT/HA12157NT Gain, S/N and Vomax vs. DAC Step -25 20 Gv.Vin -20 Input level Vin (the value to be converted) (dBs) 100 -15 10 90 Vo max (dB) 0 dB = -5.2 dBs T.H.D. = 1 % -10 IAOUT gain Gv (dB) -5 0 80 S/N (dB) S/N (JIS A filter) Vo max 20 16 12 0 5 -10 70 8 10 VCC = 14 V f = 1 kHz VRI in IAOUT out 4 60 0 2 15 -20 0 10 20 DAC Step No. 30 40 Rev.4, Jun. 1997, page 46 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. DAC Step 10 0 dB = -5.2 dBs Vcc = 14 V f = 100 Hz IAOUT output level = const 3.0 Total harmonic distortion T.H.D. (%) 1.0 +10 dB 0 dB -10 dB 0.3 0.1 0.03 0.01 0 10 20 30 DAC Step 40 50 Total Harmonic Distortion vs. DAC Step 10 0 dB = -5.2 dBs Vcc = 14 V f = 1 kHz IAOUT output level = const 3.0 Total harmonic distortion T.H.D. (%) 1.0 + 10 dB 0 dB - 10 dB 0.3 0.1 0.03 0.01 0 10 20 30 DAC Step 40 50 Rev.4, Jun. 1997, page 47 of 57 HA12155NT/HA12157NT Total Harmonic Distortion vs. DAC Step 10 0 dB = -5.2 dBs Vcc = 14 V f = 10 kHz IAOUT output level = const 3.0 Total harmonic distortion T.H.D. (%) 1.0 + 10 dB 0 dB - 10 dB 0.3 0.1 0.03 0.01 0 10 20 30 DAC Step 40 50 E. Vol Max. input level Vin max (IAOUT T.H.D. = 1 %) (dB) E. Vol Max. Input Level vs. Supply Voltage 16 14 12 10 8 6 4 2 0 f = 1 kHz IAOUT out DAC Step No.= 42 8 10 12 14 16 18 Supply voltage VCC (V) Rev.4, Jun. 1997, page 48 of 57 HA12155NT/HA12157NT Electronic Volume Gain vs. Frequency 30 20 VRI in IAOUT out V CC = 14 V V in = -12 dBs DAC Step0 DAC Step20 DAC Step29 DAC Step36 DAC Step42 DAC Step47 DAC Step51 DAC Step56 DAC Step62 100 1k Frequency (Hz) 10 k 100 k Electronic volume gain (dB) 10 0 -10 -20 -30 -40 -50 -60 -70 10 Level Meter Output vs. Input Level (HA12155) 4.0 3.0 Level meter output (V) -20 dB Range 2.0 0 dB Range 1.0 0 -80 -60 -40 -20 0 dB = 580 mVrms VCC = 14 V f = 1 kHz 0 20 40 Input level Vin (dB) Rev.4, Jun. 1997, page 49 of 57 HA12155NT/HA12157NT Level Meter Output vs. Input Level (HA12157) 4.0 3.0 Level meter output (V) -20 dB Range 2.0 0 dB Range 1.0 0 dB = 775 mVrms VCC = 14 V f = 1 kHz 0 -80 -60 -40 -20 0 20 40 Input level Vin (dB) Level Meter Output vs. Frequency 3.2 3.0 VCC = 14 V Level meter output (V) 2.8 2.6 2.4 2.2 2.0 20 30 0 dB Range Vin = 0 dB -20 dB Range Vin = -20 dB 100 300 1k 3k 10 k 30 k 100 k Frequency (Hz) Rev.4, Jun. 1997, page 50 of 57 HA12155NT/HA12157NT Level Meter Output vs. Supply Voltage 4.0 0 dB Range Vin = 12 dB 3.0 Level meter output (V) 0 dB Range Vin = 0 dB -20 dB Range Vin = -20 dB 2.0 1.0 0 dB Range Vin = -20 dB f = 1 kHz 0 8 10 12 14 16 18 Supply voltage VCC (V) Equalizer Gain vs. Frequency 40 (1) (2) (3) (4) (5) (6) NN HN NC HC NM HM RGP 33 k 33 k 33 k 33 k 47 k 47 k RGL 33 k 33 k 51 k 51 k 51 k 51 k RGH 33 k 33 k 51 k 51 k 51 k 51 k RF/Q 51 k 20 k 51 k 20 k 51 k 20 k RFQ 51 k 27 k 51 k 27 k 51 k 27 k RFM 100 k100 k 100 k100 k100 k100 k (5) (3) (6) (4) Equalizer gain (dB) 25 VCC = 14 V Vin = -20 dBs (1) (2) 10 10 300 1k 3k Frequency (Hz) 10 k 30 k 100 k Rev.4, Jun. 1997, page 51 of 57 HA12155NT/HA12157NT Equalizer Total Harmonic Distortion vs. Output Level 30 VCC = 14 V 0 dB = -5 dBs Rload = 10 k RGL = 33 k RGH = 33 k RFM = 100 k RGP = 33 k RF/Q = 51 k RFQ = 51 k : 15 kHz : 10 kHz : 6.3 kHz : 3.15 kHz : 1 kHz : 315 Hz Total hrmonic distortion T.H.D. (%) 10 3.0 1.0 0.3 0.1 -10 -5 0 5 10 15 20 Output level Vout (dB) 35 Equalizer amplifier gain GL (dB) Equalizer Amplifier Gain (GL) vs. RGL VCC = 14V RGH = R GP = 33 k RFQ = R F/Q = 51 k RFM = 100 k f = 315 Hz f = 1 kHz 30 25 20 15 10 at R GL = 33 k V out = 5 dBs 5 5k 10 k 30 k 100 k R GL ( ) 300 k 1M Rev.4, Jun. 1997, page 52 of 57 HA12155NT/HA12157NT Equalizer Amplifier Gain (GH) vs. RGH 35 Equalizer amplifier gain GH (dB) 30 25 20 15 10 VCC = 14 V R GL = 33 k R GP = 16 k R FQ = R F/Q = 24 k R FM = 390 k f = 6.3 kHz at RGH = 33 k Vout = 5 dBs 5 5k 10 k 30 k 100 k RGH ( ) 300 k 1M Equalizer Amplifier Gain (GP) vs. RGP 50 VCC = 14 V R GH = R GP = 33 k R FQ = R F/Q = 51 k R FM = 100 k f = 19 kHz 35 30 25 20 5k 10 k Equalizer amplifier gain GP (dB) 45 40 30 k 100 k R GP ( ) 300 k 1M Rev.4, Jun. 1997, page 53 of 57 HA12155NT/HA12157NT 100 k Equalizer Cut off Frequency (FM) vs. R FM Equalizer cut off frequency FM (Hz) 30 k VCC = 14 V RGL = 120 k RGH = 7.5 k RFQ = R F/Q = 24 k RGP = 16 k 10 k 3k 1k 300 5k 10 k 30 k 100 k R FM ( ) 300 k 1M 300 k Equalizer Peak Frequency vs. RFQ Equalizer peak frequency fo (Hz) 100 k 30 k R F/Q = 12 k 24 k 51 k 100 k 200 k 390 k 10 k 3k 2k 5k 10 k 30 k 100 k R FQ ( ) 300 k 1M Rev.4, Jun. 1997, page 54 of 57 HA12155NT/HA12157NT Equalizer Q vs. R FQ 15 Equalizer quality factor Q 10 5 R F/Q = 390 k 200 k 100 k 51 k 24 k 12 k 0 5k 10 k 30 k 100 k R FQ ( ) 300 k 1M Rev.4, Jun. 1997, page 55 of 57 HA12155NT/HA12157NT Package Dimensions Unit: mm 64 57.6 58.5 Max 33 1 1.46 Max 1.0 32 2.54 Min 5.08 Max 17.0 18.6 Max 19.05 0.51 Min 0.25 - 0.05 0 - 15 Hitachi Code JEDEC Code EIAJ Code Weight + 0.11 1.78 0.25 0.48 0.10 DP-64S -- SC-553-64A 8.8 g Rev.4, Jun. 1997, page 56 of 57 HA12155NT/HA12157NT Disclaimer 1. Hitachi neither warrants nor grants licenses of any rights of Hitachi's or any third party's patent, copyright, trademark, or other intellectual property rights for information contained in this document. Hitachi bears no responsibility for problems that may arise with third party's rights, including intellectual property rights, in connection with use of the information contained in this document. 2. Products and product specifications may be subject to change without notice. Confirm that you have received the latest product standards or specifications before final design, purchase or use. 3. Hitachi makes every attempt to ensure that its products are of high quality and reliability. However, contact Hitachi's sales office before using the product in an application that demands especially high quality and reliability or where its failure or malfunction may directly threaten human life or cause risk of bodily injury, such as aerospace, aeronautics, nuclear power, combustion control, transportation, traffic, safety equipment or medical equipment for life support. 4. Design your application so that the product is used within the ranges guaranteed by Hitachi particularly for maximum rating, operating supply voltage range, heat radiation characteristics, installation conditions and other characteristics. Hitachi bears no responsibility for failure or damage when used beyond the guaranteed ranges. Even within the guaranteed ranges, consider normally foreseeable failure rates or failure modes in semiconductor devices and employ systemic measures such as failsafes, so that the equipment incorporating Hitachi product does not cause bodily injury, fire or other consequential damage due to operation of the Hitachi product. 5. This product is not designed to be radiation resistant. 6. No one is permitted to reproduce or duplicate, in any form, the whole or part of this document without written approval from Hitachi. 7. Contact Hitachi's sales office for any questions regarding this document or Hitachi semiconductor products. Sales Offices Hitachi, Ltd. Semiconductor & Integrated Circuits. Nippon Bldg., 2-6-2, Ohte-machi, Chiyoda-ku, Tokyo 100-0004, Japan Tel: Tokyo (03) 3270-2111 Fax: (03) 3270-5109 URL NorthAmerica : http://semiconductor.hitachi.com/ Europe : http://www.hitachi-eu.com/hel/ecg Asia : http://sicapac.hitachi-asia.com Japan : http://www.hitachi.co.jp/Sicd/indx.htm For further information write to: Hitachi Europe GmbH Electronic Components Group Dornacher Strae 3 D-85622 Feldkirchen, Munich Germany Tel: <49> (89) 9 9180-0 Fax: <49> (89) 9 29 30 00 Hitachi Europe Ltd. Electronic Components Group. Whitebrook Park Lower Cookham Road Maidenhead Berkshire SL6 8YA, United Kingdom Tel: <44> (1628) 585000 Fax: <44> (1628) 585160 Hitachi Asia Ltd. Hitachi Tower 16 Collyer Quay #20-00, Singapore 049318 Tel : <65>-538-6533/538-8577 Fax : <65>-538-6933/538-3877 URL : http://www.hitachi.com.sg Hitachi Asia Ltd. (Taipei Branch Office) 4/F, No. 167, Tun Hwa North Road, Hung-Kuo Building, Taipei (105), Taiwan Tel : <886>-(2)-2718-3666 Fax : <886>-(2)-2718-8180 Telex : 23222 HAS-TP URL : http://www.hitachi.com.tw Hitachi Asia (Hong Kong) Ltd. Group III (Electronic Components) 7/F., North Tower, World Finance Centre, Harbour City, Canton Road Tsim Sha Tsui, Kowloon, Hong Kong Tel : <852>-(2)-735-9218 Fax : <852>-(2)-730-0281 URL : http://www.hitachi.com.hk Hitachi Semiconductor (America) Inc. 179 East Tasman Drive, San Jose,CA 95134 Tel: <1> (408) 433-1990 Fax: <1>(408) 433-0223 Copyright Hitachi, Ltd., 2000. All rights reserved. Printed in Japan. Colophon 2.0 Rev.4, Jun. 1997, page 57 of 57 |
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