CXA2038R

CXA2038R AFM Monaural Signal Processor for 8 mm VCR Description The CXA2038R is a bipolar IC designed as an AFM monaural signal processor for 8 mm VCRs. All functions necessary for AFM monaural are concentrated onto a single 64-pin LQFP. Features • Low supply voltage (3.15 V) design • Low power consumption (VCC=3.15 V) Recording: 65 mW Playback: 103 mW • Built-in BPF (1.5 MHz) • FM modulator center frequency made nonadjusting. • Supports NTSC and PAL • Enables both parallel and 3-line serial mode control • Supports electronic volume (EVR) control Applications 8 mm VCRs Structure Bipolar silicon monolithic IC 64 pin LQFP (Plastic) Absolute Maximum Ratings (Ta=25 °C) • Supply voltage VCC 7 V • Operating temperature Topr –20 to +75 °C • Storage temperature Tstg –65 to +150 °C • Allowable power dissipation PD 1120 mW (When mounted on board) Operating Conditions • Recommended supply voltage VCC 3.15 VCCH 4.75 • Supply voltage range VCC 3 to 5.25 VCCH 4.5 to 5.25 However, VCCH ≥ VCC V V V V Sony reserves the right to change products and specifications without prior notice. This information does not convey any license by any implication or otherwise under any patents or other right. Application circuits shown, if any, are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits. —1— E95Y03A77-TE Block Diagram NC S / HTC NC NC NC DEVADJ NC MUTE VCTH GND2 MONITOR 48 47 46 NC 45 44 43 42 41 40 39 38 NC 37 36 35 LPEMPTC 34 PLLLPF 33 LINEOUT 32 49 BPMONICT NC EPOUT BUF MUTE 31 50 PLL 30 RFSWP GNDH D.C. MUTE REC PB SP LP 51 AFLIM NC NC 52 1.5MHz VCO LIM 29 FSCIN MUTEOUT MUTE 53 POWER MUTE LPEMP S/H PG DOUB LPF PHASE COMP 28 NTSC/PAL VCCH OR LIM REC MUTE PB 54 27 MUTETC LPF 26 MIXOUT MUTE OFF DELAY 55 BPF fo ADJ VCC2 MUTE DET LINE ENC OUT NR DET 17 LINEIN 64 DEC OUT VCC1 63 ENC IN DEC IN TC NC NC NC IREF FADE IFDC RFDC GND1 ALCDET VCTTC WEIGHT NRDC TCH NC NC —2— D.C. CONTROL DOC DET 56 25 NC PMUTETC 57 REC ON 24 RECFMOUT MIC/LINE (CS) 58 FWR OFF 23 BPFMONI REC/PB (CK) BUS DECODER REC PB 59 BPF ON 1.5M BPF RF AGC 22 PBRFIN (S I) 60 21 AGC TC VCT5 61 LPF 20 NC MICIN REC PB MIC 62 19 NC ALC FADE 18 VCT SP/LP (SI/PA) CXA2038R 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 CXA2038R Pin Description Pin No. Symbol Pin voltage DC AC (VCC1, VCC2=3.15 V, VCCH=4.75 V, Ta=27 °C) Equivalent circuit Description VCC1 1 ALCDET — — 500 2µ 1k 250 GND 1 ALC time constant pin. ALC is OFF when this pin is connected to GND. 2 NC — — VCC1 3 FADE See attached sheet. 20µ — 3 50k 50k 1.24V GND EVR control pin for fader. 0 to 0.5 V with fixed gain. Increasing the applied voltage lowers the gain and causes the fader to operate. 4 NC — — 5 NC — — —3— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description VCC1 6 IREF 1.17 V — 6 GND 192 192 Pin for generating the reference current. Connect a 47 kΩ external resistor. Be careful not to cause cross talk. VCCH 7 IFDC 1.90 V — 7 1k 40k 40µ GND Signal path DC monitor pin. VCC1 8 RFDC 1.88 V — 8 26.8k 1k 60µ GND Signal path DC monitor pin. VCC1 60k 9 VCT TC 1.83 V — 9 60k 1k 50µ GND IC internal bias pin. Connect a decoupling capacitor. ∗1 10 GND1 0V — Audio system GND pin. ∗1 Externally applied voltage —4— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description VCC1 5µ 11 WEIGHT 1.18 V — 11 4.7k GND NR WEIGHT time constant pin. VCC1 12 NRDC 1.68 V — 12 147 1k 5µ GND NR block DC monitor pin. 13 TCH 0.47 V — 200 VCC1 150 13 147 10µ GND 2µ 14 NR attack/recovery time constant pins. 14 TC 1.1 V — 15 NC — — —5— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description 16 NC — — SP/LP VCCH 17 SI/PA (SP/LP) 50k — — 17 147 20µ 1.5V 4V 10µ SI/PA GND Serial/parallel (SP/LP) mode switching pin. When this pin is 4.3 V or more, the IC operates in serial control mode and mode control for the IC is performed by Pins 58 (CS), 59 (CK) and 60 (SI). When this pin is 3.5 V or less, the IC operates in parallel control mode as follows. L (0 to 1 V) LP H (2 to 3.5 V) or OPEN SP VCC1 5µ 18 VCT 1.23 V — 18 1k 40µ GND IC internal bias pin. Connect a decoupling capacitor. 19 NC — — 20 NC — — —6— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit VCC2 Description 21 RFAGC TC 2.3 V — 1k 21 40µ GND Pin for deciding RFAGC time constant. VCC-1.1V VCC2 22 PBRFIN — Reference input AFM 15 mVp-p 22 147 17k 17k VCC-1.15V 50µ GND Input pin for PB RF signal. The reference input level is approximately 200 mVp-p (Y + C + AFM). Note that the reference input level for the AFM component is 15 mVp-p. 100 VCC2 23 BPFMONI 1.0 V Reference output 110 mVp-p 23 1.5M BPF OUT 20µ GND Pin for monitoring the BPF output. Connect a 4.7 kΩ external resistor. 100 VCC2 24 RECFMOUT 0.9 V 1.5 MHz Reference output 210 mVp-p 24 220µ GND Recording FM modulated audio output pin. 25 NC — — —7— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description VCC2 47k 26 BPF f0 ADJ See attached sheet. 23k 20µ — 26 1k 73k VCC2/3 20µ ADJ ON/OFF GND Pin for varying the BPF fo. Non-adjusting mode when 0 to 0.8 V (VCC = 3.15 V). VCC2 1k DOC DOC 0.6µ 2.5µ 27 MUTETC 2.3 V — 27 10k 10µ GND Time constant pin for determining the MUTE OFF delay time. VCC1 40µ 28 NTSC/PAL — — 28 50k NTSC/PAL switching pin during parallel mode. L (0 to 1 V) H (2 V to VCC1) GND PAL NTSC VCC2 29 FSC IN 1.53 V Reference input 300 mVp-p 29 147 40k VCC-1.4V 40µ GND fsc input pin. The input level is 200 to 500 mVp-p. During NTSC: 3.579545 MHz During PAL: 4.433619 MHz 30 NC — — —8— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description VCC2 Input 31 147 50k 30Hz 110k 1.2V RFSWP input pin. 31 RFSWP — H (2 to VCC1) L (0 to 1V) GND 30Hz 32 NC — — VCC1 33 BPFMONI CTL — — BPF ON/OFF switch control pin. 33 147 10µ 4V GND L (0 to 3.5 V) or OPEN BPF ON H2 (4.3 V to VCCH) BPF OFF 0.08µ VCC2 34 PLLLPF — — 34 1k 25k GND 0.08µ PLL time constant pin. Since this pin has a small attraction and discharge current, signals should be received with high impedance when monitoring this pin. Also, be careful not to cause cross talk. VCC2 35 LPEMP TC 1.87 V — 35 173k 410k LPEMP time constant pin. Be careful not to cause cross talk. GND —9— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit VCC1 Description 36 DEVADJ See attached sheet. 50k — 36 60k 50k 20µ GND Deviation adjusting pin. The variable width is from 0 to VCC1. VCC1 37 MONI 1.84 V Reference output –15 dBm∗2 37 1k 20µ GND Pin for monitoring the signal before modulation during recording and after demodulation during playback. 38 NC — — 39 NC — — ∗1 40 GND2 0V — RF system GND pin. ∗1 ∗2 Externally applied voltage 0dBm=2.19 Vp-p —10— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description 41 NC — — 42 NC — — VCC1 43 VCTH 1.89 V — 43 1k RF system reference bias pin. Connect a decoupling capacitor. GND VCC1 44 SHTC 1.7 V — 44 500 1k 5µ GND S/H time constant pin. 45 NC — — —11— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description 46 NC — — 47 NC — — VCC1 Mute control pin. L (0 to 1 V) MUTE OFF H (2 V to VCC1) or OPENMUTE ON 48 MUTE ON/OFF 50k — — 48 20µ GND Mute control is possible during both serial and parallel modes. VCCH 49 LINE OUT 2.01 V 147 Reference output –7 dBm ∗1 49 36k LINEOUT pin. Set the load to 47 kΩ or more. GND VCCH 50 EPOUT 2.01 V 36k Reference output –7 dBm ∗1 50 EPOUT pin. This pin can drive a load of 120 Ω. GND ∗2 0dBm=2.19 Vp-p —12— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description ∗1 51 GNDH 0V — Output buffer system GND pin. 52 NC — — VCCH 53 MUTEOUT 0V — 53 MUTEOUT pin. This pin outputs current during muting and power ON/OFF to operate the external SW Tr. GND ∗1 54 VCCH 4.75 V — Output buffer system power supply pin. VCCH 55 MIXOUT 2.01 V 147 Reference output –7 dBm ∗2 55 36k MIXOUT pin. Set the load to 47 kΩ or more. GND ∗1 ∗2 Externally applied voltage 0dBm=2.19 Vp-p —13— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description ∗1 56 VCC2 3.15 V — RF system power supply pin. VCCH 10k 57 PMUTETC 4.75 V — 57 5k GND Time constant pin for deciding the power ON/OFF mute time. VCC1 40µ During parallel operation: MIC/LINE switching pin. L (0 to 1 V) or OPEN LINE H (2 V to VCC1) MIC During serial operation: CS input pin. 58 MIC/LINE (CS) — — 58 50k 1.5V GND VCC1 40µ During parallel operation: REC/PB switching pin. L (0 to 1 V) or OPEN REC H (2 V to VCC1) PB During serial operation: CK input pin. 59 REC/PB (CK) 50k — — 59 1.5V GND VCC1 40µ 60 SI — — 60 50k During serial operation: SI input pin. GND ∗1 1.5V Externally applied voltage —14— CXA2038R Pin No. Symbol Pin voltage DC AC Equivalent circuit Description VCCH 60k 147 61 VCT5 2.02 V — 61 60k 1k GND IC internal bias pin. Connect a decoupling capacitor. VCC1 5µ 147 62 MICIN 1.16 V 62 Reference input –38 dBm ∗2 50k VCT GND Microphone input pin. Standard input level: –38 dBm. This pin has a small input signal level and high input impedance. Therefore, be careful not to cause cross talk with other signals. ∗1 63 VCC1 3.15 V — Audio system power supply pin. VCC1 5µ 147 64 LINE IN 1.16 V 64 Reference input –38 dBm ∗2 50k VCT GND Line input pin. Standard input level: –38 dBm. This pin has a small input signal level and high input impedance. Therefore, be careful not to cause cross talk with other signals. ∗1 ∗2 Externally applied voltage 0dBm=2.19 Vp-p —15— Electrical Characteristics Reference signal source set to “b” Measurement method Unit Max. Min. Typ. 1 3 22 29 31 33 44 62 64 tion condi rement Level Frequency V3 V26 V33 V36 V44 VCC1, VCC2=3.15 V, VCCH=4.75 V, Ta=27 °C Control voltage point Switch condition, normally Ratings Mode Measu Measurement input No. Item Symbol signal conditions Input pin Level Frequency Input pin Current consumption b l1 During serial no signal 12 16 20 mA 1 during recording 1 IREC1 VCC1 + VCC2 systems b l2 During serial no signal 2 Current consumption 3 4 mA 2 during recording 2 IREC2 VCCH system c l1 During serial no signal Current consumption 21 28 35 mA 3 during playback 1 IPB1 VCC1 + VCC2 systems c l2 Current consumption During serial no signal 2 3 4 mA 4 during playback 2 IPB2 VCCH system b P49 MIC in LINE OUT a 5 reference output level VLNOL SG62 –38 dBm 1 kHz –8 –7 –6 dBm MIC in LINE OUT a 6 reference output HLNO SG62 –38 dBm 1 kHz b P49 Measure the THD to the 10 th. —16— a 0.2 % distortion b ALC level 1 7 (REF + 20 dB) VALC20 SG62 –18 dBm 1 kHz P49 –5 –2 1 dBm ALC level 2 8 (REF + 36 dB) VALC36 SG62 –2 dBm 1 kHz a b P49 –3 0 3 dBm Obtain with the ratio of a ALC effects +36 dB 9 VALC SG62 1 kHz b P49 +36 dB/+20 dB. VALC36/VALC20 b a 0 0.6 2.5 dB (+36 dB/+20 dB) /+20 dB ALC maximum input P49 Measure the THD to the 10 th. 1 % 10 distortion HALCH SG62 –2 dBm 1 kHz (REF + 36 dB) b a a FADER maximum VCC1 11 attenuation VFAL SG62 –38 dBm 1 kHz P49 A weight –69 dBm FADER dead voltage CXA2038R 12 level VFALO SG62 –38 dBm 1 kHz 0.5 V a a b P49 Obtain with VFALO/VLNOL. –0.5 0 0.5 dB Measurement input Reference signal source set to “b” Measurement method Unit Max. Min. Obtain with the ratio of a 1 3 22 29 31 33 44 62 64 tion condi rement Level Frequency V3 V26 V33 V36 V44 No. point Typ. Item Symbol signal conditions Control voltage Switch condition, normally Ratings Mode Measu Input pin Level Frequency Input pin EE system frequency b P49 20 kHz/1 kHz. FLN20/VLNOL Obtain with the ratio of a 13 response FLN20 SG62 –38 dBm 20 kHz –3 0 1 dB (20 kHz/1 kHz) b P49 FLN60/VLNOL b P49 A weight 60 kHz/1 kHz. EE system frequency 14 response FLN60 SG62 –38 dBm 60 kHz –10 dB (60 kHz/1 kHz) 15 MIC IN output noise NLN –69 dBm LINE in LINE OUT a 16 P49 reference output level VLNOLL SG64 –38 dBm 1 kHz a –8 –7 –6 dBm LINE in LINE OUT a 17 P49 reference output HLNOL SG64 –38 dBm 1 kHz a Measure the THD to the 10 th. 0.2 % distortion a —17— a a 18 LINE IN output noise NLNL P49 A weight –69 dBm Cross talk between 19 input switches VCTL SG64 –28 dBm 1 kHz a P49 A weight –67 dBm EE system MUTE b P49 Measure the EE system output DC level difference during MUTE ON/OFF. b a 20 switching level VMDC –100 0 +100 mVp-p difference LINE maximum a Measure the output level P49 when THD = 1 %. 21 output VLNMX SG62 1 kHz 0.5 dBm LINE MUTE 22 attenuation VLNML SG62 –38 dBm 1 kHz a f P49 A weight –75 dBm NR encode VNRL a 23 reference output 38 SG62 –38 dBm 1 kHz b P37 –16.6 –14.6 –12.6 dBm Obtain with a VNRL 24 NR encode linearity CXA2038R 78 SG62 –73 dBm 1 kHz b P37 –73 dBm/–33 dBm. VNRL73/VNRL33 –22.5 –21.5 –20.5 dB Measurement input Reference signal source set to “b” Measurement method Unit Max. Min. Measure the ratio of a 1 3 22 29 31 33 44 62 64 tion condi rement Level Frequency V3 V26 V33 V36 V44 No. point Typ. Item Symbol signal conditions Control voltage Switch condition, normally Ratings Mode Measu Input pin Level Frequency Input pin NR encode b P37 f = 10 kHz/1 kHz. VNRF14/NRL38 f = 2 kHz a 25 frequency response FNR14 SG62 –38 dBm 10 kHz 3.9 4.9 5.9 dB REC LP d/b P37 LP/SP. f = 10 kHz a 26 frequency response 1 FLP2 SG62 –38 dBm 2 kHz Obtain with the ratio of 1.6 2.1 2.5 dB REC LP d/b P37 LP/SP. b P24 Obtain with the ratio of 27 frequency response 2 FLP10 SG62 –38 dBm 10 kHz 2.5 3.0 3.5 dB Oscillator frequency a 28 1.5 MHz FVCO1 SG29 200 mVp-p 3.579545 MHz 1.4995 1.5 1.5005 MHz (NTSC) e P24 Oscillator frequency a 29 1.5 MHz FVCO2 SG29 200 mVp-p 4.433619 MHz 1.4995 1.5 1.5005 MHz (PAL) b —18— SG29 200 mVp-p 3.579545 MHz a SG29 200 mVp-p 3.579545 MHz a 30 REC FM output level VFML P24 187 208 229 mVp-p 31 REC FM output secondary distortion VFMH1 b P24 –45 –25 dB REC FM output SG29 200 mVp-p 3.579545MHz a 32 tertiary distortion VFNH2 b P24 –50 –30 dB AF LIM SG29 200 mVp-p 3.579545 MHz 33 characteristics VAFLM SG62 –18 dBm 10 kHz a a b P24 91 110 130 kHz DEV variable Adju SG29 200 mVp-p 3.579545 MHz sting 34 width 1.5 M VDEV SG62 –38 dBm 1 kHz a a b P36 Adjustment method noted separately. 0.1 2.9 V Reference FM SG29 200 mVp-p 3.579545 MHz VDEV a value a 35 modulation distortion VRECH SG62 –38 dBm 1 kHz b P24 Measurement method noted separately. 0.4 % 36 RFAGC level 1 VAGCL1 SG22 150 mVp-p 7 MHz SG29 200 mVp-p 3.579545 MHz VCCH a a a c P23 110 mVp-p CXA2038R Measurement input Reference signal source set to “b” condi rement No. Measurement method Unit Max. Min. Typ. Level Frequency V3 1 3 22 29 31 33 44 62 64 V26 V33 V36 V44 tion Item point Symbol signal conditions Control voltage Switch condition, normally Mode Measu Ratings Input pin Level Frequency Input pin 37 SG29 200 mVp-p 3.579545 MHz VCCH a a a RFAGC level 2 VAGCL2 SG22 300 mVp-p 7 MHz c P23 166 mVp-p 38 SG29 200 mVp-p 3.579545 MHz VCCH a a a RFAGC level 3 VAGCL3 SG22 600 mVp-p 7 MHz c P23 167 mVp-p 1.4 MHz, SG29 200 mVp-p 3.579545MHz sting a a Adju 39 P26 separately. BPF ADJ voltage VBPAJ SG22 15 mVp-p c Adjustment method noted 1.2 3 V 1.6 MHz BPF MONI level VBPAJ SG29 200 mVp-p 3.579545 MHz value a a 40 P23 1.5 MHz VBPML SG22 15 mVp-p 1.5 MHz c 110 mVp-p Obtain the ratio of VBPAJ SG29 200 mVp-p 3.579545 MHz value a a Frequency response c P23 41 0.8 M/1.5 M FBP0.8 SG22 15 mVp-p 0.8 MHz 0.8 MHz/1.5 MHz. FBP0.8/VBPML Obtain the ratio of –31 –28 dB Frequency response VBPAJ SG29 200 mVp-p 3.579545 MHz value a a 42 1.3 M/1.5 M FBP1.3 SG22 15 mVp-p 1.3 MHz c P23 1.3 MHz/1.5 MHz. FBP1.3/VBPML Obtain the ratio of –15 –8 dB —19— VBPAJ SG29 200 mVp-p 3.579545 MHz value a a PBRFIN → BPFMONI c Frequency response P23 43 1.4 M/1.5 M FBP1.4 SG22 15 mVp-p 1.4 MHz 1.4 MHz/1.5 MHz. FBP1.4/VBPML Obtain the ratio of c –6 –2 dB PBRFIN → BPFMONI VBPAJ SG29 200 mVp-p 3.579545 MHz value a a Frequency response P23 44 1.6 M/1.5 M FBP1.6 SG22 15 mVp-p 1.6 MHz 1.6 MHz/1.5 MHz. FBP1.6/VBPML Obtain the ratio of c –6 –2 dB PBRFIN → BPFMONI VBPAJ SG29 200 mVp-p 3.579545 MHz value a a Frequency response P23 45 1.7 M/1.5 M FBP1.7 SG22 15 mVp-p 1.7 MHz 1.7 MHz/1.5 MHz. FBP1.7/VBPML Obtain the ratio of c a a –15 –8 dB PBRFIN → BPFMONI VBPAJ SG29 200 mVp-p 3.579545 MHz value Frequency response P23 46 2.5 M/1.5 M FBP2.5 SG22 15 mVp-p 2.5 MHz 2.5 MHz/1.5 MHz. FBP2.5/VBPML –31 –28 dB PBRFIN → BPFMONI SG31 SG29 200 mVp-p 3.579545 MHz value 3 Vp-p 30 Hz VBPAJ 1.5 MHz VDEV a value a a 47 Demodulation level VPBL SG22 15 mVp-p DEV±60 kHz c P49 –9.8 –7.8 –5.8 dBm fs=1 kHz SG31 SG29 200 mVp-p 3.579545 MHz 3 Vp-p 30 Hz VBPAJ value VDEV a value a a Demodulation 1.5 MHz 48 distortion factor HPB SG22 15 mVp-p DEV±60 kHz c P49 0.25 0.5 % CXA2038R fs=1 kHz Measurement input Reference signal source set to “b” Measurement method Unit Max. Min. Typ. 1 3 22 29 31 33 44 62 64 tion condi rement Level 3 Vp-p a SG29 200 mVp-p 3.579545 MHz value value a a 30 Hz VBPAJ VDEV Frequency V3 V26 V33 V36 V44 No. point Item Symbol signal conditions Control voltage Switch condition, normally Ratings Mode Measu Input pin SG31 Level Frequency Input pin 49 P49 A weight Demodulation noise NPB SG22 15 mVp-p 1.5 MHz c –75 dBm DOC detection VBPAJ SG29 value 200 mVp-p 3.579545 MHz 2.4 V a a a Obtain the value for a c P37 where 15 mVp-p = 0 dB. See Fig. 1. Obtain the ratio of b/a. VBPAJ SG29 value 200 mVp-p 3.579545 MHz 2.4 V a a a See 50 sensitivity a VDOC1 SG22 1.5 MHz –17.5 –12.5 –7.5 dB (during SP) c P37 See Fig. 1. Obtain the value for a VBPAJ SG29 200 mVp-p 3.579545 MHz value 2.4 V a a a Fig. 1 Hysteresis b VDOC2/VDOC1 See 1.5 MHz 51 VDOC2 SG22 1 2 4.5 dB (during SP) Fig. 1 30 %AM DOC detection c P37 See Fig. 1. c P49 See 1.5 MHz 52 sensitivity a VDOC3 SG22 where 15 mVp-p = 0 dB. –20.5 15.5 10.5 dB (during LP) SG31 a SG29 200 mVp-p 3.579545 MHz value a 3 Vp-p 30 HZ VBPAJ Fig. 1 30 %AM 1.5 MHz MUTE OFF DELAY See 53 TMUON SG22 Tone 420 530 640 µs T1 Fig. 2 Burst SG31 a SG29 200 mVp-p 3.579545 MHz value a 3 Vp-p 30 HZ VBPAJ 1.5 MHz See 54 MUTE hold time T2 TMUOF SG22 Tone c P49 120 150 180 ms Fig. 2 —20— SG31 2.4 V a a a a SG29 200 mVp-p 3.579545 MHz value 3 Vp-p 30 Hz VBPAJ Burst PG doubler width 55 (See Fig. 3.) TPGH SG22 15 mVp-p 1.5 MHz c 5.5 7.5 9.5 µs PG doubler delay SG31 2.4 V a a a SG29 200 mVp-p 3.579545 MHz value 3 Vp-p 30 Hz VBPAJ 56 (See Fig. 3.) TPGD SG22 15 mVp-p 1.5 MHz a c 1 2 3 µs 57 POWER ON/OFF Measure the EE system b TP49 output DC level difference during power ON/OFF. P58 b P59 P60 P58 b P59 P60 b 2 VCC V 0 1 V –100 0 +100 mVp-p NOISE NPMU CS, CK, SIN input 58 58 Low level VSIL 59 DC 60 CS, CK, SIN input 58 59 High level VSIH 59 DC 60 MUTE ON/OFF 60 CXA2038R Low level V48L 48 DC P48 0 1 V Measurement input Reference signal source set to “b” Measurement method Unit Max. Min. Typ. 1 3 22 29 31 33 44 62 64 tion condi rement Level Frequency V3 V26 V33 V36 V44 No. point Item Symbol signal conditions Control voltage Switch condition, normally Ratings Mode Measu Input pin Level Frequency Input pin MUTE ON/OFF b P48 2 VCC 61 High level V48H 48 DC V Serial/parallel b P17 0 62 Low level V17SL 17 DC 3.5 V Serial/parallel b P17 63 High level V17SH 17 DC 4.3 VCC V 64 P17 SP/LP Low level V17L 17 DC b 0 1 V 65 P17 SP/LP High level V17H 17 DC b 2 3.5 V —21— b b b b b b b b 66 NTSC/PAL Low level V28L 28 DC P28 0 1 V 67 NTSC/PAL High level V28H 28 DC P28 2 VCC V MUTE ON/OFF 68 Low level V48L 48 DC P48 0 1 V MUTE ON/OFF 69 High level V48H 48 DC P48 2 VCC V 70 MIC/LINE Low level V58L 58 DC P58 0 1 V 71 MIC/LINE High level V58H 58 DC P58 2 VCC V 72 PB/REC Low level V59L 59 DC P59 0 1 V CXA2038R 73 PB/REC High level V59H 59 DC P59 2 VCC V Mode Condition Table Electrical characteristics measurement circuit mode table Mode contents REC (LINE) REC (MIC) PB LP MODE PAL MODE REC MUTE PB MUTE Condition table during parallel Bus decoder condition table during serial V17 V28 V48 V59 Mode Value bit 0-5 bit 6 bit 7-10 bit 11 bit 12 bit 13 bit 14 bit 15 Value V58 L LINE LP PAL REC condition 0 — — — LINE LP PAL REC H MIC SP NTSC MUTE PB 1 — — — MIC SP NTSC MUTE PB L H H L L 0 0 1 1 0 0 a H H H L L 0 1 1 1 0 0 b H H H L H 0 1 1 1 0 1 c H L H L L 0 1 0 1 0 0 d H H L L L 0 1 1 0 0 0 e H H H H L 0 1 1 1 1 0 f H H H H H 0 1 1 1 1 1 g —22— Note) • bit 6 should be “0”. • During serial control, set switches 58, 59 and 60 to “a”, and V17 to 4.3 to VCCH. During parallel control, set switches 58, 59 and 60 to “b”, and V17 to L (0 to 1 V) during LP and H (2 V to 3.5 V) during SP. CXA2038R Electrical Characteristics Measurement Circuit V44 SW44 V48 b 1000p S / HTC 47µ GND2 MUTE VCTH MONITOR LPEMPTC 0.22µ 48 47 46 45 44 40 37 36 35 34 33 43 42 41 39 38 TP49 47K 1K 2.2µ 49 SW31 50 BUF MUTE b PLLLPF BPMONICT NC NC NC NC NC NC NC DEVADJ 220p 1M 470K 0.47µ a b a V33 V36 32 NC LINEOUT 8 120 22µ EPOUT PLL RFSWP 31 a 10K SG31 51 D.C. MUTE REC GNDH AFLIM 30 NC 0.01µ CCA 1.5MHz VCO b 10K NC 52 PB SP LP LIM 29 Fsc IN SW29 28 NTSC/PAL 220p 27 a MUTEOUT SG29 V28 53 MUTE POWER MUTE MUTEOUT LPEMP S/H PG DOUB LPF PHASE COMP I2 A 54 OR LIM LPF 100µ 0.01µ 47µ 55 REC MUTE PB VCCH MUTETC VCCH = 4.75V MUTE OFF DELAY 1K 2.2µ 26 BPF fo ADJ 47K MIXOUT 10K V26 25 NC I1 A MUTE DET 100µ 57 VCC2 56 47µ D.C. 47µ µCOM 59 REC PB b BUS DECODER SW59 60 1.5M BPF BPF ON RF AGC 22 PB RF IN SW22 a SI V59 REC/PB (CK) a 3300p 21 AGC TC SG22 b SW60 61 LPF (S I) 10µ 20 NC SG62 62 REC PB MIC VCT5 a 0.22µ 19 NC ENC IN DEC IN b SW62 63 ALC LINE MIC IN FADE 10µ 18 VCT VCC1 SG64 64 DET a 0.22µ ENC OUT NR 17 SP/LP (SI / PA) b SW64 DEC OUT V17 1 2 FADE ALCDET 3 4 NC 5 NC 6 IREF TC 7 7 IFDC 8 RFDC 9 VCTTC 10 GND1 11 WEIGHT 12 NRDC 13 TCH 14 15 NC 16 NC NC 47K 4.7µ 4.7µ 1µ 10µ 4.7µ 100µ 22µ SW1 1M a b SW3 V3 0.22µ 22µ CXA2038R b a 22K 4.7K OFF —23— 58 CONTROL DOC DET VCC=3.15V 0.01µ 24 REC ON PMUTETC FWR RECFMOUT CS a b SW58 23 MIC/LINE (CS) BPFMONI b CK V58 a CXA2038R Input/Output Waveform Fig. 1 Pin 22 input waveform b a Level when the 1.5 MHz signal is AM modulated (2 mVp-p to 20 mVp-p) at 1 kHz and the 1.5 MHz, 15 mVp-p input is set to 0 dB. Pin 37 output waveform Fig. 2 1ms 200ms 1.5MHz DEV±60kHz fS=1kHz Pin 22 input waveform 15m Vp-p T1 Pin 37 output waveform T2 Fig. 3 Pin 31 input waveform Pin 37 output waveform PGD delay PGD width Adjustment and measurement methods • DEV adjustment method Input the reference input (–38 dBm, 1 kHz) to the MIC input and adjust the voltage applied to Pin 36 so that the Pin 24 output reference frequency deflection is 1.5 MHz ±62.8 kHz. When adjusting DEV, connect a 10 kΩ load resistor between Pin 24 and GND. • Reference modulation distortion factor Demodulate the Pin 24 output into the audio signal with the reference demodulator under the same conditions as for DEV adjustment above, then measure the distortion factor. • BPF f0 adjustment method Input 15 mVp-p, 1.4 MHz and 1.6 MHz signals to Pin 22 and adjust the voltage applied to Pin 26 so that the 1.4 MHz and 1.6 MHz levels output to Pin 23 are equal. Note that since adjustment OFF mode results when the Pin 26 voltage is between 0 to 0.8 V, the BPF f0 should be adjusted with the Pin 26 voltage between 1.2 to 3 V (when VCC1 = 3.15 V). When adjusting the BPF f0, connect a 4.7 kΩ load resistor between Pin 23 and GND. —24— CXA2038R Mode Control Tables Parallel CTL mode table Pin CTL voltage Symbol No. LOW (0 to 1 V) OPEN HIGH1 (2 V to VCC1) HIGH2 (2 V to 3.5V) HIGH3 (4.3 V to VCCH) 17 SP/LP LP SP — SP SERIAL∗1 28 NTSC/PAL PAL — NTSC — — 33 BPF ON/OFF BPF ON BPF ON — BPF ON 1.5 MBPFOFF 48 MUTE MUTE OFF MUTE ON MUTE ON — — 58 MIC/LINE LINE LINE MIC — — 59 REC/PB REC REC PB — — ∗1 When Pin 17 is 4.3 V or more, the IC operates in serial control mode. Serial CTL mode table When Pin 17 is 4.3 V or more, the IC operates in serial control mode. bit No. 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 CTL value — — — — — — — — — — — — — L — — — — — — — — MIC/LINE switching L H SP/LP switching L H NTSC/PAL switching L H MUTE L H PB/REC L H Control name VCC1 CK 0 VCC1 SI 0 CS VCC1 0 Data latch 2 µs or more 2 µs or more Mode — — — Pin Symbol No. 58 CS 59 CK 60 SI CTL voltage LOW (0 to 1 V) OPEN HIGH (2 V to VCC) L L H L L H L L H Note) bit 6 should normally be set to LINEIN MICIN LP SP PAL NTSC OFF MUTEON REC PB Input conditions Item Symbol Min. Clock frequency fck Setup time tsu 400 Hold time tHLD 400 CS fall time to SI start time t1 2 Final CK rise time to t2 2 CS rise time Typ. Max. 800 Unit kHz ns ns µs µs 0 1 2 3 15 —25— CXA2038R FADER characteristics A-Weight BPF fo characteristics 0 -10 1. 6 -20 -30 -40 -50 -60 -70 -80 0 Pin 23 BPF MONITOR output frequency (MHz) 2.0 1.0 Pin 3 FADER control voltage (V) 3.0 Pin 49 EPOUT output level (dBm) 1. 5 1. 4 1.3 1. 21 2 3 Pin 26 BPF fo control voltage (V) DEV width characteristics 200 Pin 24 REC FMOUT output DEV width (kHz) 150 100 50 0 0 1 2 Pin 36 DEV control voltage (V) 3 —26— MUTE 1000p 47µ DEV ADJ GND2 MONITO R MUTE S / HTC VCTH LPEMPTC 0.22µ 48 47 46 45 44 40 37 36 35 34 33 43 42 41 39 38 1k 2.2µ PLLLPF BPMONICT NC NC NC NC NC NC NC DEVADJ 220p 1M 470k 0.47µ Application Circuit 49 32 NC LINEOUT 120 22µ 50 BUF MUTE EPOUT PLL RFSWP 31 RF SWP 10k 51 D.C. MUTE REC GNDH AFLIM 30 NC 0.01µ 1.5MHz VCO 10k NC 52 PB SP LP LIM 29 Fsc IN Fsc IN MUTEOUT 53 MUTE POWER MUTE VCCH = 4.75V MUTEOUT LPEMP S/H PG DOUB LPF PHASE COMP 28 NTSC/PAL 220p 27 NTST / PAL 100µ 54 VCCH OR LIM LPF 0.01µ 47µ 55 REC MUTE PB MUTETC 1k MUTE OFF DELAY 2.2µ 26 BPF fo ADJ BPF f0 ADJ MIXOUT 10k VCC=3.15V 100µ MUTE DET 0.01µ 57 VCC2 56 25 NC 47µ D.C. 47µ 24 REC ON VCC1 LINE ENC OUT DEC OUT 63 ALC FADE ENC IN DEC IN TC IREF IFDC RFDC FADE ALCDET VCTTC GND1 22k 47k WEIGHT NRDC 4.7µ 4.7µ 1µ TCH 10µ 4.7µ 1M 100µ 22µ FADER CTL 0.22µ 22µ —27— 58 CONTROL DOC DET PMUTETC FWR OFF RECFMOUT MIC/LINE (CS) 23 MIC/LINE (CS) BPFMONI REC / PB(CK) BUS DECODER PB REC 59 1.5M BPF BPF ON RF AGC 22 PB RF IN PB RF IN REC/PB (CK) 3300p 21 AGC TC SI (S I) LPF 60 10µ 61 VCT5 20 NC 0.22µ 62 REC PB MIC MIC IN 19 NC 10µ 18 VCT MIC IN 0.22µ 64 DET NR 17 SP/LP (SI/ PA) SP/ LP LINEIN 1 2 NC 3 4 NC 5 NC 6 7 7 8 9 10 11 12 13 14 15 NC 16 NC CXA2038R CXA2038R Package Outline Unit : mm 64PIN LQFP (PLASTIC) 12.0 ± 0.2 ∗ 48 49 10.0 ± 0.1 33 32 A 64 1 0.5 16 0.13 M + 0.2 1.5 – 0.1 17 (0.22) + 0.08 0.18 – 0.03 + 0.05 0.127 – 0.02 0.1 0.1 ± 0.1 0° to 10° 0.5 ± 0.2 NOTE: Dimension “∗” does not include mold protrusion. DETAIL A PACKAGE STRUCTURE PACKAGE MATERIAL SONY CODE EIAJ CODE JEDEC CODE LQFP-64P-L01 LQFP064-P-1010 LEAD TREATMENT LEAD MATERIAL PACKAGE MASS EPOXY RESIN SOLDER/PALLADIUM PLATING 42/COPPER ALLOY 0.3g —28— 0.5 ± 0.2 (11.0)