CXA3562AR LCD Driver Description The CXA3562AR is a driver IC developed for use with Sony polycrystalline silicon TFT LCD panels. It supports digital 2-parallel and single input, and the input data is analog demultiplexed into 12 phases and output. The CXA3562AR can directly drive an LCD panel, and the VCOM setting circuit and precharge pulse waveform generator are also on-chip. 100 pin LQFP (Plastic) Features • Supports 10-bit 2-parallel and single input • Supports signals up to UXGA (1/2 clock when using UXGA signals) • Low output deviation by on-chip output offset cancel circuit • Supports both line inversion and dot and line inversion • On-chip timing generator with ECL • VCOM voltage generation circuit • Precharge pulse waveform generation circuit Applications LCD projectors and other video equipment Absolute Maximum Ratings (VSS = 0V) • Supply voltage VCC 16 V VDD 5.5 V • Operating temperature Topr –20 to +70 °C • Storage temperature Tstg –65 to +150 °C • Allowable power dissipation PD 2000 mW Recommended Operating Conditions • Supply voltage VCC 15.0 to 15.5 VDD 4.75 to 5.25 • Operating temperature Topr –20 to +70 V V °C 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– E01820A22 CXA3562AR SH_OUT1 NC VCOM_OUT VCOM_OFST VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST Block Diagram and Pin Configuration 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 D_A9 76 50 PVCC SID Gen. D_A8 77 VCOM Gen. 49 SH_OUT2 Vref Gen. D_A7 78 48 NC Line Inv. D_A6 79 Offset Cancel 47 SH_OUT3 D_A5 80 Line Inv. 46 NC Offset Cancel Line Inv. 45 SH_OUT4 Offset Cancel Line Inv. 43 SH_OUT5 D_A4 81 D_A3 82 D_A2 83 D/A D_A1 84 S/H S/H S/H S/H S/H S/H S/H S/H S/H 44 NC 42 NC Offset Cancel Line Inv. D_A0 85 S/H S/H S/H GND 86 S/H S/H S/H S/H S/H S/H Offset Cancel 38 PGND GND 89 S/H S/H S/H Line Inv. 37 GND GND 90 S/H S/H S/H 36 GND S/H S/H S/H Offset Cancel Line Inv. S/H S/H S/H D_B6 94 S/H S/H S/H D_B5 95 S/H S/H S/H D_B9 91 D_B8 92 D_B7 93 D/A D_B4 96 D_B3 97 D_B2 98 D_B1 99 FRP_OD FRP_EV TG 40 GND Offset Cancel Line Inv. GND 87 GND 88 41 SH_OUT6 39 GND 35 SH_OUT7 Offset Cancel Line Inv. 34 NC Offset Cancel Line Inv. 32 NC 33 SH_OUT8 Offset Cancel Line Inv. 31 SH_OUT9 Offset Cancel Line Inv. 29 SH_OUT10 Offset Cancel 27 SH_OUT11 30 NC 28 NC D_B0 100 26 PVCC Offset Cancel Level Gen. POSCTR3 SH_OUT12 POSCTR2 NC POSCTR1 DCFBOFF POSCTR0 CAL_IL SHST GND FRP CAL_IH MCLKX CAL_OH TEST –2– CAL_OL 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 SIG_OFST 8 SIG.C 7 GND 6 GND 5 GND 4 GND 3 GND 2 SHTEST 1 MCLK CAL_PLS CXA3562AR Pin Description Pin No. Symbol I/O Standard voltage level I PECL differential (amplitude 0.4V or more between VDD to 2V) or TTL input Equivalent circuit Description VDD 2 3 MCLK MCLKX 140k 8k 140k 100µ 60k 1k 2 1k 3 60k Dot clock input. PECL differential input or TTL input. For TTL input, input to MCLK and connect MCLKX to GND through a capacitor. GND VDD 50k 4 FRP I High: ≥2.0V Low: ≤0.8V 192 4 LCD panel AC drive inversion timing input. High: inverted Low: non-inverted See the Timing Chart. GND VDD 50k 5 SHST I 192 High: ≥2.0V Low: ≤0.8V 5 GND VDD 6 7 8 9 POSCTR0 POSCTR1 POSCTR2 POSCTR3 50k I High: ≥2.0V Low: ≤0.8V 192 6 8 7 9 Internal sample-and-hold timing circuit reset pulse input. This pin is also used as the offset cancel level insertion timing input. A reset is applied to the internal timing generator at the falling edge. Output phase adjustment. The output phase is adjusted in MCLK period units when SL_DAT (Pin 72) is high, and in 1/2 MCLK period units when SL_DAT is low. GND VDD VCC 20µ 30k 16 SIG.C I 1 to 5.0V 16 Signal center voltage (inversion folded voltage) adjustment input. The SH_OUT output center voltage can be adjusted in the range from 7.0 to 8.0V. GND VDD VCC 10µ 30k 17 SIG_OFST I 0 to 5.0V 17 GND –3– Output signal offset adjustment from signal center voltage. The SH_OUT output 100% white level (at 3FF input) voltage can be adjusted in the range from 0 to 1V from the center voltage. CXA3562AR Pin No. Symbol I/O Standard voltage level Equivalent circuit Description VCC 40µ 18 19 CAL_OL CAL_OH O 1k 3.0 to 6.0V 9.0 to 12.0V Level output for canceling the offset between channels. Connect directly to CAL_IL and CAL_IH, respectively. 145 18 19 GND Level input for canceling the offset between channels. Connect directly to CAL_OL and CAL_OH, respectively. When using two CXA3562R, connect the CAL_IL and CAL_IH of both chips to the CAL_OL and CAL_OH of only one CXA3562R. VCC 20k 21 22 CAL_IH CAL_IL O 9.0 to 12.0V 3.0 to 6.0V 30k 21 22 20µ GND VDD 24k 24k 24 DCFBOFF I 145 GND 24 Offset cancel function off. Normally connect to GND to use with the offset cancel function on. High (offset cancel function off) when open. GND PVCC 25 27 25, 29, 33, 41, 45, 49, 27, 31, SH_OUT12 35, to 43, SH_OUT1 47, 51 29 31 300 33 35 O 1.5 to 13.5V 41 43 300 45 47 Demultiplexed output of AC inverse driven video signals. Can be connected directly to the LCD panel. 49 51 GND VCC 80µ 100k 53 VCOM_OUT O 500 145 53 5.0 to 8.0V 500 LCD panel common voltage output. Can be set in the range from the SH_OUT center potential Vsig.c to Vsig.c – 2V by VCOM_OFST. GND VDD VCC 80µ 2k 54 VCOM_OFST I 0 to 5.0V 54 100 GND –4– LCD panel common voltage adjustment. VCOM_OUT can be set in the range from the SH_OUT center potential Vsig.c to Vsig.c – 2V by inputting 0 to 5V. CXA3562AR Pin No. Symbol I/O Standard voltage level Equivalent circuit Description VCC Precharge waveform output. SID_OUTX outputs the inverse of SID_OUT based on the output center voltage. These pins cannot directly drive the LCD panel, so input to the LCD panel with an external a buffer. 100k 0.2p 56 57 SID_OUTX SID_OUT O 145 1.5 to 13.5V 56 57 100k 0.2p GND VDD VCC Precharge level setting. Adjusts the SID_OUT and SID_OUTX output potential. PRG_LV is reflected when the PRG input pin (Pin 60) is high, and SID_LV is reflected when PRG is low. 29µ 58 59 PRG_LV SID_LV I 1.0 to 5.0V 50k 58 50k 59 GND VDD VCC 100k 60 PRG I 10k High: ≥2.0V Low: ≤0.8V 60 50µ Timing pulse input for switching the Pins 56 and 57 output levels. (See PRG_LV (Pin 58) and SID_LV (Pin 59).) GND VDD 70µ 68 VREF_I I 3.2V 10µ 68 1k 33.3k Internal D/A converter reference voltage input. Normally connect directly to VREF_O. 280µ GND VDD 2k 69 VREF_O O 69 3.2V 20k 20µ Reference voltage output. Normally connect directly to VREF_I, and connect to GND through a 0.5 to 1.0µF capacitor. 12.4k GND VDD 50k 70 F/H_CNT I High: ≥2.0V Low: ≤0.8V Open: Low 192 70 200k GND –5– SH_OUT output timing selection. High: SH_OUT1 to SH_OUT6 and SH_OUT7 to SH_OUT12 are output at different timing. Low: SH_OUT1 to SH_OUT12 are output at the same timing. CXA3562AR Pin No. Symbol I/O Standard voltage level Equivalent circuit Description VDD 70k 66 PS I Test. Normally connect to VDD. 66 5V 180k 30µ GND 38 PGND 26, 50 PVCC GND Power GND. 15.5V Power VCC. 55 VCC 15.5V 15V power supply. 67 VDD 5V 5V power supply. 11 to 15, 20, 36, 37, 39, GND 40, 61 to 65, 86 to 90 23, 30, 34, 44, 48, GND. GND 28, 32, 42, NC 46, 52 VDD 2k 1µ 192 1, 75 TEST O DAC output monitor test. Normally connect to VDD. 1 1.7 to 3.2V 75 20µ GND VDD 20k 250k 10 SHTEST I 2.5V 20k 20k 20k Test. Leave open. 192 10 250k 10µ 10µ GND VDD 50k 71 DIRC I High: ≥2.0V Low: ≤0.8V 192 71 GND –6– Scan direction setting. High: output as a time series in ascending order of output pin symbol (in order from SH_OUT1 to SH_OUT12) Low: output in descending order CXA3562AR Pin No. Symbol I/O Standard voltage level Equivalent circuit Description VDD 50k 72 SL_DAT I High: ≥2.0V Low: ≤0.8V Open: Low 192 72 200k Digital input mode switch setting. High: single input from the A port Low: parallel input from both the A and B ports GND VDD 73 SL_SCN I High: ≥2.0V Low: ≤0.8V Open: High 200k 50k 192 73 GND VDD 50k 74 SL_INV I High: ≥2.0V Low: ≤0.8V Open: Low 192 74 200k GND A and B port input switching interlocked/non-interlocked setting relative to scan direction setting during parallel input. High: A and B port switching interlocked to DIRC Low: fixed regardless of DIRC SH_OUT odd-numbered and even-numbered output polarity inverted/non-inverted setting. High: odd-numbered and evennumbered outputs inverted Low: non-inverted VDD 50k 76 to 85 D_A9 to D_A0 I High: ≥2.0V Low: ≤0.8V 192 A port digital data input. 76 to 85 GND VDD 50k 91 to 100 D_B9 to D_B0 I High: ≥2.0V Low: ≤0.8V 192 91 to 100 GND –7– B port digital data input. CXA3562AR Electrical Characteristics Measurement Circuit VDD 1µ 47p 47p VCC SH_OUT1 NC VCOM_OUT VCOM_OFST VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 100 26 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 PVCC SH_OUT2 360p NC SH_OUT3 360p NC SH_OUT4 360p NC SH_OUT5 360p NC SH_OUT6 360p GND GND PGND GND GND SH_OUT7 360p NC SH_OUT8 360p NC SH_OUT9 360p NC SH_OUT10 360p NC SH_OUT11 360p PVCC A 25 SH_OUT12 1 DCFBOFF D_B0 39 NC D_B1 51 87 CAL_IL D_B2 52 40 CAL_IH D_B3 53 41 GND D_B4 54 86 CAL_OH D_B5 55 85 CAL_OL D_B6 56 42 SIG_OFST D_B7 57 84 SIG.C D_B8 58 43 GND D_B9 59 83 GND GND 60 44 GND GND 61 82 GND GND 62 45 GND GND 63 81 SHTEST GND 64 46 POSCTR3 D_A0 65 47 POSCTR2 D_A1 66 80 POSCTR1 D_A2 67 79 POSCTR0 D_A3 68 48 SHST D_A4 69 78 FRP D_A5 70 49 MCLKX D_A6 71 77 MCLK D_A7 72 360p 50 TEST D_A8 73 A 76 VDD D_A9 74 SL_DAT SL_INV TEST 75 SL_SCN VDD A VCC 360p VCC 15.5V –8– VDD 5V CXA3562AR Electrical Characteristics No. Item Symbol 1 Digital input resolution n 2 Digital input setup time TS 3 Digital input hold time 4 Measurement points Measurement conditions Min. Typ. Max. Unit — 10 — bit SHST, D_A[9:0] and D_B[9:0] minimum setup time relative to MCLK input. (PELL) 2 — — ns TH SHST, D_A[9:0] and D_B[9:0] minimum hold time relative to MCLK input. (PECL) 3 — — ns MCLK input frequency range 1 fMCLK1 SL_DAT: 5V; maximum frequency at which the internal timing generator and D/A converter operate normally. 30 — 80 MHz 5 MCLK input frequency range 2 fMCLK2 SL_DAT: 0V; maximum frequency at which the internal timing generator and D/A converter operate normally. 60 — 100 MHz 6 VREF_O output VVREF_O voltage range Measure the VREF_O (Pin 69) voltage. 3.10 3.20 3.32 V 7 SH_OUT amplitude 1 VSHOUT1p-p VOUT1 Measure the SH_OUT1 voltage difference at D_A[9:0]: 000h and 3FFh. 4.44 4.50 4.83 V 8 SH_OUT amplitude 2 VSHOUT2p-p VOUT2 Measure the SH_OUT2 voltage difference at D_B[9:0]: 000h and 3FFh. 4.44 4.50 4.83 V 9 SH_OUT minimum amplitude VOUTMINp-p VOUT1 Lower the VREF_I voltage and adjust the amplitude; minimum amplitude at which SH_OUT1 can be output at D_B[9:0]: 000h and 3FFh. 4 — — 160 300 — V/µs V SROUT VOUT1 to VOUT12 Load capacitance = 360pF; measure slew rate at 10 to 90% of output waveform rise and fall when D_A[9:0] is varied from 000h to 3FFh and from 3FFh to 000h. VMIN VOUT1 to VOUT12 Minimum voltage at which sampleand-hold outputs VOUT1 to VOUT12 can be output. 1.5 — — V VMAX VOUT1 to VOUT12 Maximum voltage at which sampleand-hold outputs VOUT1 to VOUT12 can be output. — — 13.6 V Output deviation 13 between DOUT1 channels 1 VOUT1 to VOUT12 Value obtained by subtracting minimum VOUT1 to VOUT12 value from maximum VOUT1 to VOUT12 value at D_A[9:0]: 200h and D_B[9:0]: 200h. — 3 10 mVp-p Output deviation 14 between DOUT2 channels 2 VOUT1 to VOUT12 Value obtained by subtracting minimum VOUT1 to VOUT12 value from maximum VOUT1 to VOUT12 value at D_A[9:0]: 000h or 3FFh and D_B[9:0]: 000h or 3FFh. — 10 40 mVp-p VOUT1 to VOUT12 Value obtained by subtracting minimum VOUT1 to VOUT12 value from maximum VOUT1 to VOUT12 value at D_A[9:0]: 200h and D_B[9:0]: 200h. (when using two CXA3562R) — 10 — mVp-p 10 SH_OUT slew rate SH_OUT 11 minimum output voltage SH_OUT 12 maximum output voltage 15 Output deviation DIC1 between ICs 1 –9– CXA3562AR No. 16 Item Measurement Symbol points Measurement conditions Min. VOUT1 to VOUT12 Value obtained by subtracting minimum VOUT1 to VOUT12 value from maximum VOUT1 to VOUT12 value at D_A[9:0]: 000h or 3FFh and D_B[9:0]: 000h or 3FFh. (when using two CXA3562R) — 20 — ASID1 VSID_LV VSID VSIDX PRG: 0V; measure VSID_LV and VSID at FRP: 0V, and VSID_LV and VSIDX at FRP: 5V. Calculate as ASID1 = VSID(X)/VSID_LV. 1.9 2.0 2.1 times ASID2 VPRG_LV VSID VSIDX PRG: 5V; measure VPRG_LV and VSID at FRP: 0V, and VPRG_LV and VSIDX at FRP: 5V. Calculate as ASID2 = VSID(X)/VPRG_LV. 1.9 2.0 2.1 times VSID VSIDX Load capacitance = 47pF, PRG: 0V; input a repeating high/low pulse to FRP (Pin 4), and apply DC input voltage so that VSID and VSIDX are 2.5V/11.5V. Measure slew rate at 10 to 90% of output waveform rise and fall. 15 50 — V/µs VOUT1 VOUT1 center voltage when SIG.C (Pin 16) is varied from 1 to 5V. 7 — 8 V 0 — 1 V Vc – 2.5 — Vc V Output deviation DIC2 between ICs 2 SID output 17 gain 1 SID output 18 gain 2 19 SID output slew rate 20 Signal center VSIG adjustable range SRSID Typ. Max. Unit mVp-p 21 SH_OUT offset VSIGOFST adjustable range VOUT1 D_A[9:0]: 3FFh, FRP: 0V, D_B[9:0]: 3FFh; value obtained by subtracting VOUT1 from VOUT1 center voltage when SIG_OFST (Pin 17) is varied from 1 to 5V. 22 VCOM VCOM adjustable range VCOM VCOM_OUT voltage when VCOM_OFST (Pin 54) is varied from 0 to 5V. 23 VDD current consumption IDD IVDD IDD = IVDD 59 85 112 mA 24 VCC current consumption ICC IVCC1 IVCC2 ICC = IVCC1 + IVCC2 (no digital data input) 21 40 59 mA Current consumption in 25 IPS power saving mode IVDD IVCC1 IVCC2 GND (Pin 66), ICC = IVDD + IVCC1 + IVCC2 31 47 65 mA 26 Differential linearity error 27 Integral linearity ILE error DLE — VVREF_I = 3.2V –0.7 — 0.7 LSB — VVREF_I = 3.2V –1.2 — 1.2 LSB – 10 – CXA3562AR Description of Operation The flow of internal operations is described below. The digital signals input to D_A9 to D_A0 and D_B9 to D_B0 are internally D/A converted into approximately 1.5V (at VREF_I: 3.2V) analog signals. After that, the signal that has been demultiplexed into 12 phases is amplified by a factor of three times, inverted at the signal center potential according to FRP, and output. The output level relative to the digital input changes according to the following settings. A: SIG_OFST voltage B: VREF_I voltage VCC C: SIG.C voltage B A Signal Center A 1023 C B 512 0 GND Digital IN SH_OUT 1. Digital input block The CXA3562AR can be set to single input from only the A port or parallel input from both the A and B ports, and port switching by right/left inversion is also possible in parallel input mode. This makes it possible to support various systems. In single input mode, the signal is internally demultiplexed to 2-parallel format and input to the D/A converter. 2. D/A converter block The internal D/A converter has two systems for odd-numbered and even-numbered outputs. The voltage input from VREF_I becomes the 100% white level potential of the analog converted signal, and this amplitude is a maximum 1.5Vp-p with respect to input data of 000h to 3FFh. 3. Sample-and-hold (S/H) block The odd-numbered and even-numbered D/A converter outputs are input to the odd-numbered and evennumbered sample-and-hold blocks, respectively. The signals are converted from time series signals into 6-phase cyclic parallel signals by the sample-and-hold group which is appropriately controlled by the internal timing generator. For forward scan, the signals are output in the ascending order of SH_OUT1, SH_OUT2, SH_OUT3 ... SH_OUT12. For reverse scan, this order is inverted and the signals are output in descending order. Connect the signals to the LCD panel according to the order used. The timing of each sample-and-hold pulse is shown on the following pages. These pulses are not output and are used only inside the IC. – 11 – CXA3562AR Single input mode DAC 10bit D_A[9:0] D_A1 D D DAC_O D_A2 D D S/H DAC D_B2 S/H D MCLK MCLK/2 D_A[9:0] 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 MCLK D_A1 0 1 2 D_A2 D_B2 DAC_O 0 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 1 3 5 7 9 11 13 15 17 19 21 23 25 27 2 4 6 8 10 12 14 16 18 20 22 24 26 28 1 3 DIRC: H SH1_1_2 SH1_3_4 SH1_5_6 SH1_7_8 SH1_9_10 SH1_11_12 SH2_1_6 SH2_7_12 F/H_CNT: L SH3A_1_12 CH1 to CH12 simultaneous output timing F/H_CNT: H SH3B_1_6 CH1 to CH6 simultaneous output timing CH7 to CH12 simultaneous output timing SH3B_7_12 DIRC: L SH1_1_2 SH1_3_4 SH1_5_6 SH1_7_8 SH1_9_10 SH1_11_12 SH2_1_6 SH2_7_12 F/H_CNT: L SH3A_1_12 CH1 to CH12 simultaneous output timing F/H_CNT: H SH3B_1_6 CH1 to CH6 simultaneous output timing CH7 to CH12 simultaneous output timing SH3B_7_12 – 12 – CXA3562AR 2-parallel input mode DAC 10bit D_A[9:0] DAC_O D_A2 D D D S/H DAC 10bit D_B[9:0] D_B2 D S/H D MCLK D_A[9:0] –3 –1 1 3 5 7 9 11 13 15 17 19 21 23 25 27 D_B[9:0] –2 0 2 4 6 8 10 12 14 16 18 20 22 24 26 28 MCLK D_A2 –5 –3 –1 1 3 5 7 9 11 13 15 17 19 21 23 25 D_B2 –4 –2 0 2 4 6 8 10 12 14 16 18 20 22 24 26 –1 1 DAC_O 3 DIRC: H SH1_1_2 SH1_3_4 SH1_5_6 SH1_7_8 SH1_9_10 SH1_11_12 SH2_1_6 SH2_7_12 F/H_CNT: L SH3A_1_12 CH1 to CH12 simultaneous output timing F/H_CNT : H SH3B_1_6 CH1 to CH6 simultaneous output timing CH7 to CH12 simultaneous output timing SH3B_7_12 DIRC: L SH1_1_2 SH1_3_4 SH1_5_6 SH1_7_8 SH1_9_10 SH1_11_12 SH2_1_6 SH2_7_12 F/H_CNT: L SH3A_1_12 CH1 to CH12 simultaneous output timing F/H_CNT: H SH3B_1_6 CH1 to CH6 simultaneous output timing CH7 to CH12 simultaneous output timing SH3B_7_12 – 13 – CXA3562AR 4. Timing generator (TG) block The internal timing generator operates by one pair of differential clock inputs (MCLK, MCLKX) and a horizontal sync signal input (SHST), and generates the timing pulses needed by the demultiplexer block, dot inversion control pulse and output deviation cancel circuit. The various operating modes can be designated by the pin settings. The SHST and FRP inputs should satisfy the relationship shown in the figure below with the MCLK and MCLKX input period as 1clk. SHST FRP 30clk or more 1µs or more The CXA3562AR can select various operating modes according to the timing generator block settings. These settings are described below. • SL_DAT (Pin 72) Digital input selection. Single input from only the A port is selected when set to high level, and parallel input from both the A and B ports is selected when set to low level. When inputting a 2-parallel processed digital video signal in parallel input mode, input the earlier time series data to the A port and the later time series data to the B port. Input a master clock having the same period as the input data rate to MCLK in both modes. This pin is low level (2-parallel input mode) when left open. • DIRC (Pin 71), SL_SCN (Pin 73) Scan direction settings. Output is ascending order when DIRC is set to high level, and inverted to descending order (SH_OUT1 to SH_OUT12) when set to low level. At this time if SL_SCN is set to high, the A and B port data can be switched by switching DIRC between high and low. When SL_SCN is set to low, the A port data is output from the odd-numbered SH_OUT and the B port data is output from the even-numbered SH_OUT regardless of the DIRC setting. Set SL_SCN to high when SL_DAT is high. D_A[9:0] A1 A2 A3 A4 A5 A6 D_B[9:0] B1 B2 B3 B4 B5 B6 DIRC: L DIRC: H SL_SCN: L SH_OUT1: A6, SH_OUT2: B6, SH_OUT3: A5, SH_OUT4: B5, SH_OUT5: A4, SH_OUT6: B4, SH_OUT7: A3, SH_OUT8: B3, SH_OUT9: A2, SH_OUT10: B2, SH_OUT11: A1, SH_OUT12: B1 SH_OUT1: A1, SH_OUT2: B1, SH_OUT3: A2, SH_OUT4: B2, SH_OUT5: A3, SH_OUT6: B3, SH_OUT7: A4, SH_OUT8: B4, SH_OUT9: A5, SH_OUT10: B5, SH_OUT11: A6, SH_OUT12: B6 SL_SCN: H SH_OUT1: B6, SH_OUT2: A6, SH_OUT3: B5, SH_OUT4: A5, SH_OUT5: B4, SH_OUT6: A4, SH_OUT7: B3, SH_OUT8: A3, SH_OUT9: B2, SH_OUT10: A2, SH_OUT11: B1, SH_OUT12: A1 SH_OUT1: A1, SH_OUT2: B1, SH_OUT3: A2, SH_OUT4: B2, SH_OUT5: A3, SH_OUT6: B3, SH_OUT7: A4, SH_OUT8: B4, SH_OUT9: A5, SH_OUT10: B5, SH_OUT11: A6, SH_OUT12: B6 – 14 – CXA3562AR • SL_INV (Pin 74) Dot inversion and line inversion selection. When set to low level, all SH_OUT channels are output at the same polarity as shown by the solid line in the figure below. When set to high level, the odd-numbered and evennumbered SH_OUT outputs are output at inverse polarities. At this time the odd-numbered outputs are inverted when the FRP pulse is high, and non-inverted when the FRP pulse is low. Conversely, the evennumbered outputs are inverted when the FRP pulse is low, and non-inverted when the FRP pulse is high. SH_OUT GND FRP • F/H_CNT (Pin 70) SH_OUT output timing phase setting. When set to low level, all SH_OUT outputs are output at the same timing. When set to high level, SH_OUT1 to SH_OUT6 and SH_OUT7 to SH_OUT12 are output at phases offset by 1/2 clock period from each other. SH_OUT7 to 12 SH_OUT7 to 12 SH_OUT1 to 6 SH_OUT1 to 6 GND GND F/H_CNT: H F/H_CNT: L • Output phase setting The phase of each SH_OUT output can be adjusted in MCLK period units when SL_DAT is high or in 1/2 MCLK period units when SL_DAT is low by POSCTR[3:0] (Pins 6 to 9). The phase can be set in 16 ways by 4-bit digital input. The output phase shifts backward by the above unit each time this setting is increased by one bit. – 15 – CXA3562AR 5. Calibration level generator block The CXA3562AR generates the offset cancel circuit reference with a calibration level generator in order to minimize the deviation between channels at the center level. The 200h output level is generated at both the AC output high and low sides, and these levels are DC output from CAL_OH and CAL_OL, respectively. At the same time, 200h data is forcibly inserted into the video signal while the video blanking period SHST pulse is low level, and feedback is applied so that the output levels of all SH_OUT channels conform to CAL_IH and CAL_IL during this period. Video signal replacement period SHST FRP 200ns CAL_PLS (internal pulse) Offset cancel operation 000h 200h SH_OUT Signal center Delayed by sample-and-hold 200h 000h 6. SID signal generator block This circuit generates the precharge signal waveform used by the LCD panel. The voltage input from PRG_LV (Pin 58) and SID_LV (Pin 59) is switched by the PRG pulse (Pin 60). The PRG_LV voltage is selected when PRG is high, and the SID_LV voltage is selected when PRG is low. This signal is then further amplified by a factor of two times and folded by the FRP pulse. The folded center voltage is the SH_OUT center voltage (voltage set by the SIG.C pin). SID_OUT (Pin 57) is inverted when FRP is high, and non-inverted when FRP is low. Conversely, SID_OUTX (Pin 56) is inverted when FRP is low, and noninverted when FRP is high. SID_OUT and SID_OUTX cannot directly drive the precharge signal input of the LCD panel, so they should be connected via a buffer having sufficient current supply capability. 7. VCOM potential generator block This block sets the DC common potential for the LCD panel. VCOM_OFST (Pin 54) sets the deviation relative to the SH_OUT center potential, which is set by SIG.C. – 16 – CXA3562AR Example of Representative Characteristics (VCC = 15.5V, VDD = 5.0V, Ta = 25°C) VREF_I voltage vs. SH_OUT voltage white-black amplitude Input data vs. SH_OUT voltage 14 4.7 <Measurement conditions> SIG.C = 3.75V SIG_OFST = 3.6V 4.6 12 FRP = High 4.5 SH_OUT voltage [V] SH_OUT white-black amplitude voltage [V] 4.8 4.4 4.3 4.2 4.1 10 8 6 FRP = Low 4 2 3.9 3.8 2.8 2.9 3.0 3.1 3.2 0 000h 3.3 VREF_I voltage [V] 200h 300h 3FFh SIG_OFST voltage vs. SH_OUT voltage SIG.C voltage vs. SH_OUT center voltage 12 11 8.5 <Measurement conditions> SIG_OFST = 3.6V 8.0 10 SH_OUT voltage [V] SH_OUT center voltage [V] 100h Input data (10 bits) 9.0 7.5 7.0 6.5 6.0 FRP = High 9 8 7 6 5 5.5 4 <Measurement conditions> SIG.C = 3.75V FRP = Low DATA = 200h 3 5.0 2.5 3.0 3.5 0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5 5.0 4.5 4.0 SIG_OFST voltage [V] SIG.C voltage [V] VCOM_OFST voltage vs. VCOM_OUT voltage 7.5 <Measurement conditions> SIG.C = 3.75V 7.0 VCOM_OUT voltage [V] <Measurement conditions> SIG.C = 3.75V SIG_OFST = 3.6V 4.0 6.5 6.0 5.5 5.0 4.5 0.0 1.0 2.0 3.0 4.0 5.0 VCOM_OFST voltage [V] – 17 – CXA3562AR SID_LV voltage vs. SID_OUT voltage PRG_LV voltage vs. SID_OUT voltage 16 16 <Measurement conditions> SIG.C = 3.75V 14 12 12 SID_OUT voltage [V] SID_OUT voltage [V] <Measurement conditions> SIG.C = 3.75V 14 FRP = High 10 8 6 FRP = Low FRP = High 10 8 6 FRP = Low 4 4 2 2 0 0 0 1 2 3 0 4 SID_LV voltage [V] 1 2 PRG_LV voltage [V] – 18 – 3 4 CXA3562AR Application Circuit 1 (to XGA Panel) VDD 20kΩ VDD 0.1µF Buffer 20kΩ 1 Psig DSD CXD3511Q VDD 10Ω PRG 161 VDD 10Ω RGT 136 20kΩ 0.1µF VDD 47µF VDD 1Ω 1µF 31 COM 0.1µF VDD 1Ω SH_OUT1 NC 3 Vsig1 VCOM_OUT VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST 10kΩ VCOM_OFST VDD 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 R1OUT9 122 R1OUT8 121 R1OUT7 120 R1OUT6 119 R1OUT5 118 R1OUT4 117 R1OUT3 116 R1OUT2 113 R1OUT1 112 R1OUT0 111 10Ω D_A9 10Ω D_A8 10Ω D_A7 10Ω D_A6 10Ω D_A5 10Ω D_A4 10Ω D_A3 10Ω D_A2 10Ω D_A1 10Ω D_A0 GND GND GND GND GND D_B9 D_B8 D_B7 D_B6 D_B5 D_B4 D_B3 D_B2 D_B1 D_B0 76 50 77 49 78 48 79 47 80 46 81 45 82 44 83 43 84 42 85 41 86 40 87 39 CXA3562AR 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 100 26 PVCC 1Ω SH_OUT3 5 Vsig3 NC 1Ω SH_OUT4 6 Vsig4 NC 1Ω SH_OUT5 7 Vsig5 NC 1Ω SH_OUT6 8 Vsig6 GND GND LCD Panel LCX023 PGND GND GND 1Ω SH_OUT7 9 Vsig7 NC 1Ω SH_OUT8 10 Vsig8 NC 1Ω SH_OUT9 11 Vsig9 NC 1Ω SH_OUT10 12 Vsig10 NC 1Ω SH_OUT11 PVCC 13 Vsig11 VCC 47µF 10kΩ SH_OUT12 DCFBOFF NC CAL_IL CAL_IH GND CAL_OL CAL_OH SIG_OFST GND SIG.C GND GND GND GND 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 SHTEST 8 POSCTR3 7 POSCTR2 6 POSCTR1 5 POSCTR0 FRP 4 SHST 3 MCLKX TEST MCLK 2 4 Vsig2 NC 0.1µF 1 1Ω SH_OUT2 1Ω 14 Vsig12 VDD VDD OPEN 1µF 1µF 20kΩ 10Ω FRP 157 0.1µF 10Ω SHST 159 VDD CXA3266Q VCC 20kΩ 82Ω 82Ω 130Ω 130Ω 15.5V VDD 5V 0.1µF CLKH 32 CLKL 31 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 19 – CXA3562AR Application Circuit 2 (to SXGA Panel) VDD 20kΩ VDD 0.1µF Buffer 20kΩ 1 Psig DSD CXD3511Q VDD 10Ω PRG 161 2 COMR VDD 10Ω RGT 136 20kΩ 0.1µF 21 COML VDD 47µF VDD 1Ω 1µF 32 COM 0.1µF VDD SH_OUT1 NC 3 Vsig1 VCOM_OUT VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST 10kΩ VCOM_OFST 1Ω 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 R1OUT9 122 R1OUT8 121 R1OUT7 120 R1OUT6 119 R1OUT5 118 R1OUT4 117 R1OUT3 116 R1OUT2 113 R1OUT1 112 R1OUT0 111 10Ω D_A9 10Ω D_A8 10Ω D_A7 10Ω D_A6 10Ω D_A5 10Ω D_A4 10Ω D_A3 10Ω D_A2 10Ω D_A1 10Ω D_A0 GND GND GND GND GND R2OUT9 110 R2OUT8 109 R2OUT7 108 R2OUT6 107 R2OUT5 106 R2OUT4 105 R2OUT3 104 R2OUT2 103 R2OUT1 99 R2OUT0 98 10Ω D_B9 10Ω D_B8 10Ω D_B7 10Ω D_B6 10Ω D_B5 10Ω D_B4 10Ω D_B3 10Ω D_B2 10Ω D_B1 10Ω D_B0 76 50 77 49 78 48 79 47 80 46 81 45 82 44 83 43 84 42 85 41 86 40 87 39 CXA3562AR 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 100 26 PVCC 1Ω SH_OUT3 5 Vsig3 NC 1Ω SH_OUT4 6 Vsig4 NC 1Ω SH_OUT5 7 Vsig5 NC 1Ω SH_OUT6 8 Vsig6 GND GND LCD Panel LCX028 PGND GND GND 1Ω SH_OUT7 9 Vsig7 NC 1Ω SH_OUT8 10 Vsig8 NC 1Ω SH_OUT9 11 Vsig9 NC 1Ω SH_OUT10 12 Vsig10 NC 1Ω SH_OUT11 13 Vsig11 PVCC VCC 47µF 10kΩ SH_OUT12 DCFBOFF NC CAL_IL CAL_IH GND CAL_OL CAL_OH SIG_OFST GND SIG.C GND GND GND GND 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 SHTEST 8 POSCTR3 7 POSCTR2 6 POSCTR1 5 POSCTR0 FRP 4 SHST 3 MCLKX TEST MCLK 2 4 Vsig2 NC 0.1µF 1 1Ω SH_OUT2 1Ω 14 Vsig12 VDD VDD OPEN 1µF 1µF 20kΩ 10Ω FRP 157 0.1µF 10Ω SHST 159 VDD CXA3266Q VCC 20kΩ 82Ω 82Ω 130Ω 130Ω 15.5V VDD 5V 0.1µF CLK/2H 30 CLK/2L 29 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 20 – CXA3562AR Application Circuit 3 (to WXGA Panel) SID_OUTX SID_OUT Another CXA3562R 56 57 Buffer 2 Psig1 3 Psig2 4 Psig3 5 Psig4 DSD CXD3511Q VDD VDD 6 COMR VDD 10Ω RGT 136 20kΩ 20kΩ 0.1µF 25 COML VDD 47µF VDD 1Ω 1µF 34 COM 0.1µF VDD 1Ω SH_OUT1 7 Vsig-a1 NC VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST 10kΩ VCOM_OUT VDD VCOM_OFST VDD 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 R1OUT9 122 R1OUT8 121 R1OUT7 120 R1OUT6 119 R1OUT5 118 R1OUT4 117 R1OUT3 116 R1OUT2 113 R1OUT1 112 R1OUT0 111 10Ω D_A9 10Ω D_A8 10Ω D_A7 10Ω D_A6 10Ω D_A5 10Ω D_A4 10Ω D_A3 10Ω D_A2 10Ω D_A1 10Ω D_A0 GND GND GND GND GND R2OUT9 110 R2OUT8 109 R2OUT7 108 R2OUT6 107 R2OUT5 106 R2OUT4 105 R2OUT3 104 R2OUT2 103 R2OUT1 99 R2OUT0 98 10Ω D_B9 10Ω D_B8 10Ω D_B7 10Ω D_B6 10Ω D_B5 10Ω D_B4 10Ω D_B3 10Ω D_B2 10Ω D_B1 10Ω D_B0 76 50 77 49 78 48 79 47 80 46 81 45 82 44 83 43 84 42 85 41 86 40 87 39 CXA3562AR 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 100 26 PVCC Vsig-a2 9 Vsig-a3 1Ω SH_OUT3 NC 1Ω SH_OUT4 10 Vsig-a4 NC 1Ω SH_OUT5 11 Vsig-a5 NC 1Ω SH_OUT6 12 Vsig-a6 GND GND LCD Panel LCX037 PGND GND GND 1Ω SH_OUT7 13 Vsig-b1 NC 1Ω SH_OUT8 14 Vsig-b2 NC 1Ω SH_OUT9 15 Vsig-b3 NC 1Ω SH_OUT10 16 Vsig-b4 NC 1Ω SH_OUT11 17 Vsig-b5 PVCC VCC 47µF 10kΩ SH_OUT12 DCFBOFF NC CAL_IL CAL_IH GND CAL_OL CAL_OH SIG_OFST GND SIG.C GND GND GND GND 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 SHTEST 8 POSCTR3 7 POSCTR2 6 POSCTR1 5 POSCTR0 FRP 4 SHST 3 MCLKX TEST MCLK 2 8 NC 0.1µF 1 1Ω SH_OUT2 1Ω 18 Vsig-b6 VDD VDD OPEN 1µF 1µF 20kΩ 10Ω FRP 157 0.1µF 10Ω SHST 159 VDD CXA3266Q VCC 20kΩ 82Ω 82Ω 130Ω 130Ω 15.5V VDD 5V 0.1µF CLK/2H 30 CLK/2L 29 Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 21 – CXA3562AR Application Circuit 4 (to UXGA Panel) VDD 0.1µF 20kΩ VDD 0.1µF DSD CXD3511Q 20kΩ 10Ω PRG 161 0.47µF VDD Buffer VDD 10Ω RGT 136 1 Psig1 2 Psig2 47µF VDD VDD 0.1µF VDD 1Ω SH_OUT1 NC 11 Vsig1 VCOM_OUT VCC SID_OUTX SID_OUT PRG PRG_LV GND SID_LV GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST 10kΩ VCOM_OFST VDD 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 R1OUT9 122 R1OUT8 121 R1OUT7 120 R1OUT6 119 R1OUT5 118 R1OUT4 117 R1OUT3 116 R1OUT2 113 R1OUT1 112 R1OUT0 111 10Ω D_A9 10Ω D_A8 10Ω D_A7 10Ω D_A6 10Ω D_A5 10Ω D_A4 10Ω D_A3 10Ω D_A2 10Ω D_A1 10Ω D_A0 GND GND GND GND GND D_B9 D_B8 D_B7 D_B6 D_B5 D_B4 D_B3 D_B2 D_B1 D_B0 76 50 77 49 78 48 79 47 80 46 81 45 82 44 83 43 84 42 85 41 86 40 87 39 CXA3562AR 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 100 26 PVCC 1Ω SH_OUT3 15 Vsig5 NC 1Ω SH_OUT4 17 Vsig7 NC 1Ω SH_OUT5 19 Vsig9 NC 1Ω SH_OUT6 21 Vsig11 GND GND LCD Panel LCX036 PGND GND GND 1Ω SH_OUT7 23 Vsig13 NC 1Ω SH_OUT8 25 Vsig15 NC 1Ω SH_OUT9 27 Vsig17 NC 1Ω SH_OUT10 29 Vsig19 NC 1Ω SH_OUT11 PVCC 31 Vsig21 VCC 47µF 10kΩ SH_OUT12 DCFBOFF NC CAL_IL GND CAL_IH CAL_OH CAL_OL SIG_OFST SIG.C GND GND GND GND GND SHTEST 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 POSCTR3 8 POSCTR2 7 POSCTR1 6 POSCTR0 5 SHST 4 FRP TEST MCLK 3 MCLKX 2 13 Vsig3 NC 0.1µF 1 1Ω SH_OUT2 1Ω 33 Vsig23 OPEN VDD 0.47µF 0.47µF VDD 10Ω FRP 157 10Ω SHST 159 20kΩ Buffer 0.1µF 4 Psig4 82Ω 82Ω 130Ω 130Ω 3 Psig3 VDD VDD 20kΩ 0.1µF VDD 0.1µF 20kΩ VDD 0.47µF VDD 47µF 56 COM1 1Ω 57 COM2 0.1µF VDD SH_OUT1 NC VCC SID_OUTX SID_OUT PRG_LV SID_LV PRG GND GND GND GND GND PS VDD VREF_I VREF_O F/H_CNT DIRC SL_DAT SL_SCN SL_INV TEST VCOM_OUT 12 VSig2 10kΩ VCOM_OFST VDD 1Ω 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61 60 59 58 57 56 55 54 53 52 51 R2OUT9 110 R2OUT8 109 R2OUT7 108 R2OUT6 107 R2OUT5 106 R2OUT4 105 R2OUT3 104 R2OUT2 103 R2OUT1 99 R2OUT0 98 10Ω D_A9 10Ω D_A8 10Ω D_A7 10Ω D_A6 10Ω D_A5 10Ω D_A4 10Ω D_A3 10Ω D_A2 10Ω D_A1 10Ω D_A0 GND GND GND GND GND D_B9 D_B8 D_B7 D_B6 D_B5 D_B4 D_B3 D_B2 D_B1 D_B0 76 50 77 49 78 48 79 47 80 46 81 45 82 44 83 43 84 42 85 41 86 40 87 39 CXA3562AR 88 38 89 37 90 36 91 35 92 34 93 33 94 32 95 31 96 30 97 29 98 28 99 27 26 100 PVCC 1Ω SH_OUT3 16 Sig6 NC 1Ω SH_OUT4 18 Sig8 NC 1Ω SH_OUT5 20 Sig10 NC 1Ω SH_OUT6 22 Sig12 GND GND PGND GND GND 1Ω SH_OUT7 24 Sig14 NC 1Ω SH_OUT8 26 Sig16 NC 1Ω SH_OUT9 28 Sig18 NC 1Ω SH_OUT10 30 Sig20 NC 1Ω SH_OUT11 PVCC 32 Sig22 VCC 47µF 10kΩ SH_OUT12 DCFBOFF NC CAL_IL GND CAL_IH CAL_OH CAL_OL SIG_OFST SIG.C GND GND GND GND GND SHTEST 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 POSCTR3 8 POSCTR2 7 POSCTR1 6 POSCTR0 5 SHST 4 FRP TEST MCLK 10Ω 3 MCLKX XFRP 158 2 14 Sig4 NC 0.1µF 1 1Ω SH_OUT2 1Ω 34 Sig24 CXA3266Q VDD 0.47µF OPEN 0.47µF VCC VDD VDD CLK/2H 30 CLK/2L 29 15.5V 5V 20kΩ 0.1µF 0.1µF Application circuits shown are typical examples illustrating the operation of the devices. Sony cannot assume responsibility for any problems arising out of the use of these circuits or for any infringement of third party patent and other right due to same. – 22 – CXA3562AR Notes on Operation The CXA3562AR has high power consumption, so be sure to take the following radiation measures. • Use four-layer substrate. • GND lines connected between Pins 11 to 15, Pins 36 to 40, Pins 61 to 65 and Pins 86 to 90 should be as thick as possible. – 23 – CXA3562AR Package Outline Unit: mm 100PIN LQFP (PLASTIC) 16.0 ± 0.2 ∗ 14.0 ± 0.1 75 51 76 50 (15.0) B 26 100 1 0.5 ± 0.2 A (0.22) 25 0.5 b 0.13 M + 0.2 1.5 – 0.1 0.1 0.1 ± 0.1 0.5 ± 0.2 0˚ to 10˚ 0.125 ± 0.04 b = 0.18 ± 0.03 DETAIL B : PALLADIUM NOTE: Dimension "∗" does not include mold protrusion. DETAIL A PACKAGE STRUCTURE SONY CODE EIAJ CODE LQFP-100P-L01 P-LQFP100-14x14-0.5 JEDEC CODE – 24 – PACKAGE MATERIAL EPOXY RESIN LEAD TREATMENT PALLADIUM PLATING LEAD MATERIAL COPPER ALLOY PACKAGE MASS 0.7g Sony Corporation