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BA12

Abstract: BA21 BA11 SSOP-B40 bd3859 ba22
Text: =4.7k, IHF-A CT= 20log (O2/O1) CT= 20log (O1/O2) Fig.1 Gvmaxl -1 1 +1 dB VIN=400mVrms, From 0 to 14dB Gvmaxl= 20log (G1/VIN) Gvmaxl= 20log (G2/VIN) Fig.1 Gvmaxlst - 2 - , IHF-A Gmin0= 20log (O1/VIN) Gmin0= 20log (O2/VIN) Fig.1 GBB -2 1 +2 dB From 0 to 10dB VIN=500mVrms, f=120Hz GBB= 20log (O1/VIN) GBB= 20log (O2/VIN) Fig.1 GBC -2 1 +2 dB From -10 to 0dB VIN=500mVrms, f=120Hz GBC= 20log (O1/VIN) GBC= 20log (O2/VIN) Fig


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PDF BD3859AFV BD3859AFV SSOP-B40 0-31dB 0-56dB -10dB BASS21 BASS22 BA12 BA21 BA11 SSOP-B40 bd3859 ba22
2004 - BD3861FS

Abstract: SW11 Electronic Volume Controller IC capacitor 10u 8017A
Text: Without signal GV= 20log (O1/VIN) GV -1.5 0.0 1.5 dB Total harmonic distortion THD , 02 01 05 0D 03 0B GV= 20log (O2/VIN) µVrms Rg=0k, IHF-A CT= 20log (O2/O1) CT= 20log (O1/O2 , voltage gain1 Gvmaxl1 Input voltage gain2 Gvmaxl2 -1.5 GV6= 20log (G1/VIN) 2 2 2 2 , A5 0D 03 0B G1 Gvmaxl1= 20log (G1/VIN) VIN=200mVrms From 12 to 20dB Gvmaxl1= 20log (G2/VIN) 1 2 2 2 2 1 1 00 02 01 4 0D 03 0B F5 G1 Gvmaxl1= 20log (G1/VIN


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PDF BD3861FS BD3861FS SW11 Electronic Volume Controller IC capacitor 10u 8017A
Not Available

Abstract: No abstract text available
Text: STSENCE STSENCECOM15.734 kHz D6 STHY STSENCE STHY = 20log V STSENCE COM15 , SAPSENCECOM78.67 kHz SAP D5 SAP SAPHY SAPSENCE SAPHY = 20log V SAPSENCESAP COM78.67 kHz D5 , S12816JJ3V0DS00 µ PC1854A NOHY SAP NOSENCE NOHY = 20log V , VONONOT COM300 Hz, 100 L, R VOLR VL VOLR = 20log VR VLLOT COM300 Hz, 100 VRROT COM300 Hz, 100 VOMO1 1k VOMO1 = 20log V300 1kLOT COM1 kHz, 30 300LOT COM300 Hz, 30


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PDF PC1854A PC1854AI2CTVLSITV PC1854AI2C Vp-p100 PC1854ACT 28SDIP10 mm400 PC1854AGT 28SOP9 mm375
SAP15

Abstract: SAP 17
Text: STSENCE STSENCECOM15.734 kHz D6 STHY STSENCE STHY = 20log V STSENCE COM15 , SAPSENCECOM78.67 kHz SAP D5 SAP SAPHY SAPSENCE SAPHY = 20log V SAPSENCESAP COM78.67 kHz D5 , S12816JJ3V0DS00 µ PC1854A NOHY SAP NOSENCE NOHY = 20log V , VONONOT COM300 Hz, 100 L, R VOLR VL VOLR = 20log VR VLLOT COM300 Hz, 100 VRROT COM300 Hz, 100 VOMO1 1k VOMO1 = 20log V300 1kLOT COM1 kHz, 30 300LOT COM300 Hz, 30


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PDF PC1854A PC1854AI2CTVLSITV PC1854AI2C Vp-p100 PC1854ACT 28SDIP10 mm400 PC1854AGT 28SOP9 mm375 SAP15 SAP 17
2002 - philips sub woofer circuit diagram

Abstract: 2.1 woofer circuit diagram woofer circuit diagram sub woofer circuit toshiba v16s TA1343N GLPF210 TA1343 220 v sine wave phase shift GLPF170
Text: 40 00 00 00 40 C0 TP13 TP16 13 10 (a) SN RdB = 20log (v13s/v13n) SN LdB = 20log (v16s/v16n) Input signal (80 Hz, 100 mVrms, sine wave) to TP6 and TP8. Measure , = 20log (v12s/v12n) · Connect TP6 and TP8 to GND. · C0 Measure amplitude of T13 and , 3 · · TP16 Go WdB = 20log (v12/100) · TP13 Measure amplitude of TP12 (v12 mVrms). · TP8 GoBst RdB = 20log (v134/v133) GoBst LdB = 20log (v164/v163) · (a) Measure


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PDF TA1343N TA1343N philips sub woofer circuit diagram 2.1 woofer circuit diagram woofer circuit diagram sub woofer circuit toshiba v16s GLPF210 TA1343 220 v sine wave phase shift GLPF170
SAP6

Abstract: k3747 PC187 MOA2 PC842C W1A sot 23
Text: 15.734 kHz LEDOFFONCOM STHY COMf = 15.734 kHzLEDON LEDOFFV STHY = 20log STSENSE V , kHzSAP LEDOFFONCOM SAP SAPHY COMf = 78.67 kHzSAP LEDONOFFCOMV SAPHY = 20log SAPSENSE V , = 160 kHz, Vin = 90 mVr.m.s.NDTDC SAP LEDOFFONV NOHY = 20log NOSENSE V VOMO , ROTVROTLOTVLOT VOLR = 20log VROT VLOT VOMO1 MUTE, FMONO"L" COM30 f = 300 HzROT V300MO COM30 f = 1 kHzROT V1kMO VOMO1 = 20log V1kMO V300MO LOT VOMO2 MUTE, FMONO"L" COM30 f =


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PDF PC1876 PC1876TVLSITV PC1876GT 42SSOP9 mm375 PC1876THAT S11666JJ4V0DS00 SAP6 k3747 PC187 MOA2 PC842C W1A sot 23
2001 - TA1343

Abstract: woofer circuit diagram sub woofer 5.1 channel circuit diagram philips sub woofer circuit diagram
Text: , v161 mVrms). Go RdB = 20log (v131/500) Go LdB = 20log (v161/500) Set data of sub address 03 (h) to 04 (h). Measure amplitude of T13 and TP16 (v132 mVrms, v162 mVrms). GoAtt RdB = 20log (v132/v131) GoAtt LdB = 20log (v162/v161) Set data of sub address 03 (h) to 00 (h) and set data of sub address 07 (h) to , mVrms, v164 mVrms). GoBst RdB = 20log (v134/v133) GoBst LdB = 20log (v164/v163) Measure amplitude of TP12 (v12 mVrms). Go WdB = 20log (v12/100) Input signal (1 kHz, 500 mVrms, sine wave) to TP6 and TP8


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PDF TA1343N TA1343N TA1343 woofer circuit diagram sub woofer 5.1 channel circuit diagram philips sub woofer circuit diagram
philips sub woofer circuit diagram

Abstract: bass treble control circuit for woofer TA1343N computer sub woofer sub woofer circuit diagram SUB WOOFER CIRCUIT TA1343 woofer circuit diagram 5.1 channel surround sound IC sub woofer 5.1 channel circuit diagram
Text: = 20log (v13s/v13n) SN LdB = 20log (v16s/v16n) Input signal (80 Hz, 100 mVrms, sine wave) to TP6 , T12 (v12n mVrms). SN WdB = 20log (v12s/v12n) · Connect TP6 and TP8 to GND. · C0 , wave) to TP6 and TP8. · 3 · · TP16 Go WdB = 20log (v12/100) · TP13 Measure amplitude of TP12 (v12 mVrms). · TP8 GoBst RdB = 20log (v134/v133) GoBst LdB = 20log (v164/v163 , address 03 (h) to 00 (h) and set data of sub address 07 (h) to 10 (h). · 00 GoAtt RdB = 20log


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PDF TA1343N TA1343N philips sub woofer circuit diagram bass treble control circuit for woofer computer sub woofer sub woofer circuit diagram SUB WOOFER CIRCUIT TA1343 woofer circuit diagram 5.1 channel surround sound IC sub woofer 5.1 channel circuit diagram
2004 - 8017A

Abstract: No abstract text available
Text: - -90.0 dB dB dB From 0 to -59dB From 0 to -59dB IHF-A GminO= 20log (O1/VIN) GminO= 20log (O2/VIN) GOV= 20log (O1/VIN) GOV= 20log (O2/VIN) 1 1 1 1 1 1 - - - 2 2 2 2 2 2 2 2 2 1 1 1 10 02 DC - 02 01 01 01 05 0D 03 , GminI= 20log (O1/VIN) GminI= 20log (O2/VIN) GIV1= 20log (O1/VIN) GIV1= 20log (O2/VIN) GIV2= 20log (O1/VIN) GIV2= 20log , =200mVrms From 0 to 10dB GV6= 20log (G1/VIN) GV6= 20log (G2/VIN) Gvmaxl1= 20log (G1/VIN) Gvmaxl1= 20log (G2/VIN) 1 1 1 1 1 1 CS= 20log (G1/VIN) CS= 20log (G2/VIN) 1 1 5 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 2 1 2 2 2 2 2 2 2 2 2 2 2


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PDF BD3861FS BD3861FS 11pin) 10kHz SSOP-A32 8017A
2008 - BD3883

Abstract: No abstract text available
Text: µVrms dB dB GV= 20log (VOUT/VIN) 400 to 30kHz BPF THD=1% Rg=0k, IHF-A Rg=0k, IHF-A VIN=200mVrms GV6= 20log (VOUT/VIN) VIN=200mVrms From 0 to 10dB GvmaxI1= 20log (VOUT/VIN) VIN=200mVrms From 12 to 26dB GvmaxI2= 20log (VOUT/VIN) From 0 to 26dB 400 to 30kHz BPF THD=1% Rg=0k, IHF-A CS= 20log (VOUT/VIN) RI=51k×VOUT/ (VIN-VOUT) GRE= 20log (VOUT/VIN) From 0 to -30dB GIV1= 20log (VOUT/VIN) From 0 to -30dB *3 Input Voltage Gain 2 , Max. +1 -90.0 9 9 +2 Unit dB dB dB dB dB dB Condition From 0 to ­59dB Gov= 20log (VOUT/VIN) From 0


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PDF BD3403FV, BD3861FS, BD3883FS BD3883FS) BD3883
MOA2

Abstract: No abstract text available
Text: 15.734 kHz LEDOFFONCOM STHY COMf = 15.734 kHzLEDON LEDOFFV STHY = 20log STSENSE V , kHzSAP LEDOFFONCOM SAP SAPHY COMf = 78.67 kHzSAP LEDONOFFCOMV SAPHY = 20log SAPSENSE V , = 160 kHz, Vin = 90 mVr.m.s.NDTDC SAP LEDOFFONV NOHY = 20log NOSENSE V VOMO , ROTVROTLOTVLOT VOLR = 20log VROT VLOT VOMO1 MUTE, FMONO"L" COM30 f = 300 HzROT V300MO COM30 f = 1 kHzROT V1kMO VOMO1 = 20log V1kMO V300MO LOT VOMO2 MUTE, FMONO"L" COM30 f =


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PDF PC1876 PC1876TVLSITV PC1876GT 42SSOP9 mm375 PC1876THAT S11666JJ4V0DS00 MOA2
2002 - philips sub woofer circuit diagram

Abstract: TA1343 woofer circuit diagram 2.1 sub woofer circuit WOOFER 5.1 woofer computer sub woofer sub woofer circuit diagram GLPF170 sub woofer 5.1 channel circuit diagram
Text: 13 10 (a) SN RdB = 20log (v13s/v13n) SN LdB = 20log (v16s/v16n) Input signal (80 Hz, 100 , . Measure amplitude of T12 (v12n mVrms). SN WdB = 20log (v12s/v12n) · Connect TP6 and TP8 to GND , wave) to TP6 and TP8. · 3 · · TP16 Go WdB = 20log (v12/100) · TP13 Measure amplitude of TP12 (v12 mVrms). · TP8 GoBst RdB = 20log (v134/v133) GoBst LdB = 20log (v164/v163 , address 03 (h) to 00 (h) and set data of sub address 07 (h) to 10 (h). · 00 GoAtt RdB = 20log


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PDF TA1343N TA1343N philips sub woofer circuit diagram TA1343 woofer circuit diagram 2.1 sub woofer circuit WOOFER 5.1 woofer computer sub woofer sub woofer circuit diagram GLPF170 sub woofer 5.1 channel circuit diagram
1999 - 20LOG

Abstract: 2R10 BA3870 ghp2
Text: : GLP1 = 20log Gain of Amp A R5 R4)R5 : GA = 0 Attenuation of ATT1 Gain of Amp B (Hz) (dB) (dB) EVR R6)EV R R7)R6 : GB = 20log R7 : GATT1 = 20log (dB) (dB) Cutoff , (Hz) Gain of Amp C Gain of Amp D : GDL = 20log (dB) : GC = 0 426 R11 R10 (dB , ) Attenuation of HPF in frequency range f t fCH1 : GHP1 = 20log Attenuation of HPF in frequency range fCH2 t f : GHP2 = 20log Gain of Amp D : GDH = 20log R3 R2)R3 (dB) R3 R1//R2)R3


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PDF BA3870 BA3870 500mV 20LOG 2R10 ghp2
LC4528B

Abstract: BAS80 LA76835 CBP308 LA76835N sg445 142T2 20IRE D2006 V438
Text: 56pin 80dBµ 10kHz-4.2MHz RMS Vsn 20Log (1.0/Vsn) SG1 IC-S 56 80dBµSG176pin SG2 , =100kHz) IFSW1="OFF" fm=100kHz 75pinFM FM=±25kHz FMf SV2[mVrms] SF= 20Log (SV1/SV2) [dB] FM 90dBµ , =400Hz, SV3[mVrms] SAMR= 20Log (SV1/SV3) [dB] 90dBµ, SAMR 75pinFM400Hz AM=30% AM 75pin(DIN.AUDIO) CW SV4[mVrms] SSN= 20Log (SV1/SV4) [dB] de-emph time constant 90dBµ, SNTC 75 75pinFM2.12KHz fm=2.12KHz SV5[mVrms] FM=±25KHz SNTC= 20Log (SV1/SV5) [dB] No.7962-16/61


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PDF LA76835NM LA76835NM D2006 B8-7038 58MHz 58MHz) LC4528B BAS80 LA76835 CBP308 LA76835N sg445 142T2 20IRE V438
2010 - BD3883FS

Abstract: No abstract text available
Text: Rg0k, IHF-A VIN200mVrms GV620log(VOUT/VIN) VIN200mVrms, From 0 to 10dB GvmaxI1= 20log (VOUT/VIN , From 0 to ­59dB Gov= 20log (VOUT/VIN) From 0 to ­59dB IHF-A, GminO= 20log (VOUT/VIN) VIN=200mVrms, f=1kHz VIN=200Vrms, f=1kHz VIN=200mVrms, f=90Hz, From 0 to 14dB GBB= 20log (VOUT/VIN) VIN=200mVrms, f =90Hz, From ­14 to 0dB GBC= 20log (VOUT/VIN) VIN=200mVrms, f=90Hz VIN=200mVrms, From 0 to 12dB GMB= 20log (VOUT/VIN) VIN=200mVrms, From -12 to 0dB GMC= 20log (VOUT/VIN) VIN=200mVrms VIN=200mVrms, f=10kHz From 0 to


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PDF BD3403FV, BD3861FS, BD3883FS 10086EAT01 BD3883FS) R1010A BD3883FS
1999 - Ba3870

Abstract: 2R10
Text: : GLP1 = 20log Gain of Amp A R5 R4)R5 : GA = 0 Attenuation of ATT1 Gain of Amp B (Hz) (dB) (dB) EVR R6)EV R R7)R6 : GB = 20log R7 : GATT1 = 20log (dB) (dB) Cutoff , (Hz) Gain of Amp C Gain of Amp D : GDL = 20log (dB) : GC = 0 426 R11 R10 (dB , ) Attenuation of HPF in frequency range f t fCH1 : GHP1 = 20log Attenuation of HPF in frequency range fCH2 t f : GHP2 = 20log Gain of Amp D : GDH = 20log R3 R2)R3 (dB) R3 R1//R2)R3


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PDF BA3870 BA3870 2R10
LA76810

Abstract: LA76810HA la7681 SV6 357 CONT127 A1143 V438 3123P sg264
Text: 46pin10kHz5.0MHz RMS Vsn 20Log (1.43/Vsn) SG1 SG2 SG3 80dBµSG13pinDC V3 SG1=74dBµ,SG2=64dBµ,SG3 , ] SF= 20Log (SV1/SV2) [dB] 2pinFM 400Hz FM LEVEL= 2pinFM400Hz SV3[mVrms] SAMR= 20Log (SV1/SV3) [dB] 2pin(DIN.AUDIO) SV4[mVrms] SSN= 20Log (SV1/SV4) [dB] FM LEVEL= 90dBµ, fm=3.18KHz FM , 2pinFM3.18KHz SV5[mVrms] SPTC= 20Log (SV1/SV5) [dB] 2pinFM400Hz SV6[mVrms] SGD= 20Log (SV1/SV6) [dB] FM LEVEL= 2pinFM2.12kHz SV7[mVrms] SNTC= 20Log (SV6/SV7) [dB] SW:IF1="OFF"9pin=5V,2pin 458kHzSV8[mVrms


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PDF LA76810HA LA76810HA B8-8159 A1143-1/39 A1143-38/39 43NTSC A1143-39/39 LA76810 la7681 SV6 357 CONT127 A1143 V438 3123P sg264
Not Available

Abstract: No abstract text available
Text: V4 = 0V V 8 = 5 V V9 = 0V SG12= 10M Hzand 3.58M Hz 0. 15Vp_pCW A1fu = 20log - 20log-¡Pijr (dB , 5 V V 4 = 0 V V 8 —5 V V9 = 0V SG12 = 200kHzand3.58MHz 0 .15Vp.pCW A lfo = 20log - 20log-jpjir , defined as AmVp-p. Gain A2G = 20log-^- (dB) A M P2 Lower frequency characteristics Upper , 220kHz&3.58MHz 80mVp.pCW A 2fd = zoiog-^- - 20log- |jj- (dB) The amplitude when 10MHz is input at TP7 is , Linearity 2 -ioiog -jpg- CdB) The amplitude at TP2 is defined as A V p -p . Y C g i = 20log- |j-(dB


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PDF M52354FP M52354FP 2432QDD
2010 - BD3883FS

Abstract: SSOP-B40 BD340 BD3861FS SSOP-A32 3-band equalizer bd3883
Text: , IHF-A VIN200mVrms GV620log(VOUT/VIN) VIN200mVrms, From 0 to 10dB GvmaxI1= 20log (VOUT/VIN , From 0 to ­59dB Gov= 20log (VOUT/VIN) From 0 to ­59dB Maximum attenuation GminO - - -90.0 dB IHF-A, GminO= 20log (VOUT/VIN) Surround Gain CH1CH2 Gsur1 5 7 9 dB , to 14dB GBB= 20log (VOUT/VIN) VIN=200mVrms, f =90Hz, From ­14 to 0dB GBC= 20log (VOUT/VIN) VIN=200mVrms, f=90Hz VIN=200mVrms, From 0 to 12dB GMB= 20log (VOUT/VIN) VIN=200mVrms, From -12 to 0dB GMC= 20log


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PDF BD3403FV, BD3861FS, BD3883FS 10086EAT01 BD3883FS) R1010A BD3883FS SSOP-B40 BD340 BD3861FS SSOP-A32 3-band equalizer bd3883
LA76832

Abstract: LA76832N top22y LA76832 N PCA00554 East West PCA00560 sg445 CONT127 COIL 38.9MHz
Text: 10kHz-4.2MHz RMS (Vsn) 20Log (1.43/Vsn) IC-S 46 SG1 80dBµGS13PIN SG2 DC(V3) SG3 C-S , =±25kHz FMf (SV2:mVrms) FM STHD 2 90dBµ, SF= 20Log (SV1/SV2)[dB] 2PINFM400Hz FM LEVEL , =400Hz, (SV3:mVrms) AM=30% SAMR= 20Log (SV1/SV3)[dB] No.0069-11/48 LA76832N SIF.S/N , ) NT de-emph time constant SNTC 2 90dBµ, SSN= 20Log (SV1/SV4)[dB] 2PINFM2.12kHz FM LEVEL= fm=2.12kHz, (SV5:mVrms) FM=±25kHz SNTC= 20Log (SV1/SV5)[dB] Audio 1. BUS :AUDIO.MUTE="0",AUDIO.SW


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PDF LA76832N O0406 O3005 B8-5799 LA76832 LA76832 LA76832N top22y LA76832 N PCA00554 East West PCA00560 sg445 CONT127 COIL 38.9MHz
2010 - Not Available

Abstract: No abstract text available
Text: signal Output Voltage Gain GV -1.5 0.0 1.5 dB GV 20log (VOUT/VIN) Total Harmonic , - dB Rg0kΩ, IHF-A VIN200mVrms GV6 20log (VOUT/VIN) VIN200mVrms, From 0 to 10dB GvmaxI1= 20log (VOUT/VIN) VIN200mVrms From 12 to 26dB GvmaxI2 20log (VOUT/VIN) From 0 to 26dB , Switching Step GOVst - 1 - dB From 0 to –59dB Gov= 20log (VOUT/VIN) From 0 to –59dB Maximum attenuation GminO - - -90.0 dB IHF-A, GminO= 20log (VOUT/VIN) Surround Gain


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PDF 10086EAT01 BD3403FV, BD3861FS, BD3883FS BD3883FS)
LA76818A

Abstract: str 6654 ic str 6654 LC4528B LA76818 str W 6654 SYS1000 LA7973 DG 127 3PIN str f 6654
Text: ="1"46pinDC SG1 46 46pin 80dBµ 10kHz-5.0MHz RMS Vsn 20Log (1.43/Vsn) SG1 IC-S 46 , =100kHz 2pinFM FM=±30kHz 2 SV2[mVrms] SF= 20Log (SV1/SV2) [dB] FM STHD 90dBµ, 2 , SV3[mVrms] SAMR= 20Log (SV1/SV3) [dB] SIF.S/N SSN 90dBµ, 2 2pin(DIN.AUDIO) CW SV4[mVrms] SSN= 20Log (SV1/SV4) [dB] PAL de-emph time SPTC 90dBµ, constant 2pinFM3.18KHz fm=3.18KHz FM=±30KHz 2 SV5[mVrms] SPTC= 20Log (SV1/SV5) [dB] SGD time constant 2 SIF.SYS


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PDF N8047 LA76818A LA76818A ICLA7973) SECAMLA7642N) N2107 B8-6654 O0406 str 6654 ic str 6654 LC4528B LA76818 str W 6654 SYS1000 LA7973 DG 127 3PIN str f 6654
1999 - circuit diagram for auto on off

Abstract: BA3570FS circuit diagram for audio power amp 2R13 BA3570F als 4 pin
Text: (ATT) = 20log Amp B gain : GV(B) = 20log Amp B cutoff frequency EVR R10)EVR R7)R11 2 S R7 S C11 1 (Hz) (Hz) : GV(C) = 0 Amp D gain : GV(D) = 20log 558 (dB) 2 S , : fCL2 = (dB) : GV(MUTE) = 0 (dB) R14 (dB) R13 (dB) Amp E gain : GV(E) = 20log , (R6R8+R8R10+R6R10) S C10 frequency 2 Amp D gain : GV(D) = 20log (Hz) R13 R13+R14 (dB) R9 R8+R9 , ) The total gain GH1 for the frequency band ftfCH1 is GH1 = 20log R19+R20 Amp D' gain: GV(D) =


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PDF BA3570F BA3570FS BA3570FS 22-pin BA3570F) circuit diagram for auto on off circuit diagram for audio power amp 2R13 als 4 pin
Not Available

Abstract: No abstract text available
Text: (3)GY1 = 20log (G1 (V p-p)/0.35(Vp-p) [dB] YTMAX (1) Input signal a (f=3MHz) via SG32. (2) Measure pin @ output amplitude. It is called TY1. (3) YTMlDl= 20log (YT1/lnput amplitude) [dB] YTMIN (1) Input signal a (f=3MHz) via SG32. (2) Measure pin ® output ammplitude. It is called YT2. (3) YTMID2= 20log , called YB. (3) YBW= 20log [YB (Vp-p)/GY1 (Vp-p)][dB] DC REG1 (1) Set signal b to sync level 0, and , It via SG32. (2) Measure pin ® output annplitude(sine wave portion). It is called YL. (3) YLIN= 20log


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PDF M52300BSP M52300BSP 12C-bus 0D2G011
M52099P

Abstract: No abstract text available
Text: lo g A Q jg p - 20log (dB) SW 12 = b SW2 = ON V 2 = 5V V 4 = OV V 8 = 5V V 9 - OV SG12 = 10MHz , 9 = OV SG12 = 3.58MHz 0.1 5 & 0.45Vp - pCW 5 Gain A2G = 20log (dB) SW 10 = b V4 = OV V 8 = , defined as BV p - p. A2«j = 20log - 20log (dB) SW 10 = b V 4 = OV V 8 = 5V V 9 = OV SG10 = 220kH z & , 20log - 20log (dB) SW 10 = b V 4 = OV V8 = 5V V 9 = OV SGI 0 = 10M Hz & 3.58M Hz 50m V p - pCW 8 , p - p and the amplitude when 3.58M Hz is input is defined as BV p - p. A3fd - 20log q jg


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PDF M52099P/FP M52099 G320ENQN 2432Q 800kHz. M52099P
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