500 MILLION PARTS FROM 12000 MANUFACTURERS

DATASHEET SEARCH ENGINE

Search Stock

Shift+Click on the column header for multi-column sorting 
Part
Manufacturer
Supplier
Stock
Best Price
Price Each
Ordering
Part : AC20-LOG002 Supplier : SMC Manufacturer : Allied Electronics & Automation Stock : - Best Price : $596.2000 Price Each : $596.2000
Shipping cost not included. Currency conversions are estimated. 

20LOG

Catalog Datasheet MFG & Type PDF Document Tags

BA12

Abstract: BA21 =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
ROHM
Original
SSOP-B40 BA12 BA21 BA11 ba22 bd3859 BD3859AFV BASS21 BASS22 BASS11 BASS12

8017A

Abstract: BD3861FS 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
ROHM
Original
BD3861FS 8017A SW11 capacitor 10u Electronic Volume Controller IC MID22 MID21 MID12 MID11
Abstract: 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 NEC
Original
PC1854AI2CTVLSITV PC1854AI2C PC1854ACT 28SDIP10 PC1854AGT 28SOP9

SAP 17

Abstract: SAP15 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
NEC
Original
SAP 17 SAP15 PC1854ATHAT P28GT-50-375B-3 C10535J PC1854AGT28SOP9 IR35-00-3 VP15-00-3

philips sub woofer circuit diagram

Abstract: 2.1 woofer circuit diagram 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
Toshiba
Original
TA1343N philips sub woofer circuit diagram 2.1 woofer circuit diagram woofer circuit diagram sub woofer circuit GLPF210

SAP6

Abstract: k3747 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 =
NEC
Original
SAP6 k3747 MOA2 PC187 PC842C W1A sot 23 PC1876 PC1876TVLSITV PC1876GT 42SSOP9 PC1876THAT S11666JJ4V0DS00

TA1343

Abstract: woofer circuit diagram , 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
Toshiba
Original
TA1343 sub woofer 5.1 channel circuit diagram

philips sub woofer circuit diagram

Abstract: bass treble control circuit for woofer = 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
Toshiba
Original
bass treble control circuit for woofer computer sub woofer sub woofer circuit diagram 5.1 channel surround sound IC toshiba v16s 2.1 sub woofer circuit

8017A

Abstract: - -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
ROHM
Original
SSOP-A32

BD3883

Abstract: 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
ROHM
Original
BD3883 BD3403FV BD3883FS

MOA2

Abstract: 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 =
NEC
Original
S42GT-80-375B-2 PC1876GT42SSOP9 WS60-00-1

philips sub woofer circuit diagram

Abstract: TA1343 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
Toshiba
Original
WOOFER 5.1 woofer capacitor .33 mf G100 GLPF100 GLPF125

20LOG

Abstract: BA3870 : 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
ROHM
Original
BA3870 20LOG 2R10 ghp2

LC4528B

Abstract: BAS80 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
-
Original
LA76835NM D2006 LC4528B BAS80 LA76835 CBP308 LA76835N sg445 B8-7038 RFAGC63

BD3883FS

Abstract: 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
ROHM
Original
10086EAT01 R1010A

Ba3870

Abstract: 2R10 : 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
ROHM
Original

LA76810

Abstract: LA76810HA 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
-
Original
LA76810HA LA76810 la7681 SV6 357 3123P CONT127 B8-8159 A1143-1/39 A1143-38/39 43NTSC A1143-39/39
Abstract: 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 â'"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 -
OCR Scan
M52354FP 14P2N-A M52099P 52354FP 579545MH G320ENON

BD3883FS

Abstract: SSOP-B40 , 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
ROHM
Original
BD340 3-band equalizer

LA76832

Abstract: LA76832N 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
-
Original
LA76832 top22y LA76832 N PCA00554 COIL 38.9MHz PCA00560 O0406 O3005 B8-5799

PC1851BCU

Abstract: TLO 61 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
NEC
Original
PC1851BCU TLO 61 LPRS520 00TV PC1851B PC1851BI2CTVLSITV PC1851BI2C 42SDIP15 PC1851BGT

24PIN

Abstract: CXA2570N =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
Sony
Original
CXA2570N 24PIN E98259A98-PS SSOP-24P-L01 SSOP024-P-0056 42/COPPER

S26 photodiode

Abstract: sony CD Laser pickup - -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
Sony
Original
CXA2647N S26 photodiode sony CD Laser pickup sony Laser diode cd rom Sony RF Amplifier for CD Players pickup RFDC 30PIN SSOP-30P-L01 P-SSOP30-5

S26 photodiode

Abstract: CXA2647N = 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
Sony
Original
PHOTODIODE S27 RFC 4k fe cd-rom ic focus error signal 30-pin

8002 AUDIO amplifier

Abstract: 8002 op amp 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
Texas Instruments
Original
8002 AUDIO amplifier 8002 op amp SLOA020 8002 amplifier Mancini a2rg C011905 SLYT146
Showing first 20 results.