SOLOMON SYSTECH SEMICONDUCTOR TECHNICAL DATA SSD2123 Product Preview 480 x 272 RGB TFT LCD Driver Integrated Power Circuit, Gate and Source Driver This document contains information on a product under development. Solomon Systech reserves the right to change or discontinue this product without notice. http://www.solomon-systech.com Rev 0.30 P 1/66 SSD2123 Jan 2008 Copyright © 2008 Solomon Systech Limited CONTENTS 1 GENERAL DESCRIPTION ....................................................................................................... 5 2 FEATURES................................................................................................................................... 5 3 ORDERING INFORMATION ................................................................................................... 6 4 BLOCK DIAGRAM .................................................................................................................... 6 5 DIE PAD FLOOR PLAN ............................................................................................................ 7 6 PIN DESCRIPTION .................................................................................................................. 15 7 COMMAND TABLE ................................................................................................................. 20 8 COMMAND DESCRIPTION................................................................................................... 23 9 EXTENDED COMMAND DESCRIPTION............................................................................ 36 10 GAMMA ADJUSTMENT FUNCTION ............................................................................... 41 10.1 STRUCTURE OF GRAYSCALE AMPLIFIER ..............................................................................................................42 10.2 GAMMA ADJUSTMENT REGISTER.........................................................................................................................44 10.2.1 Gradient adjusting register.........................................................................................................................44 10.2.2 Amplitude adjusting register.......................................................................................................................44 10.2.3 Micro adjusting register..............................................................................................................................44 10.3 LADDER RESISTOR / 8 TO 1 SELECTOR .................................................................................................................45 11 BLOCK FUNCTION DESCRIPTION ................................................................................. 50 SERIAL INTERFACE ..........................................................................................................................................................50 Serial Interface – 4-wires (8 bits) ...............................................................................................................................50 Serial Interface – 3-wires (9 bits) ...............................................................................................................................51 Serial Interface – 3-wires (24 bits) .............................................................................................................................52 DATA CONTROL ..............................................................................................................................................................53 BOOSTER AND REGULATOR CIRCUIT ...............................................................................................................................53 SHIFT REGISTER ..............................................................................................................................................................53 DATA LATCHES ...............................................................................................................................................................53 RESET CIRCUIT ................................................................................................................................................................53 12 DC CHARACTERISTICS..................................................................................................... 54 13 AC CHARACTERISTICS..................................................................................................... 55 13.1 DISPLAY SIGNAL OUTPUT TIMING ........................................................................................................................55 13.2 SPI TIMING ..........................................................................................................................................................57 SERIAL PERIPHERAL INTERFACE (SPI) ............................................................................................................................57 13.3 8-BIT SERIAL INTERFACE .....................................................................................................................................63 13.4 24-BIT RGB INTERFACE ......................................................................................................................................64 14 SSD2123Z OUTPUT VOLTAGE RELATIONSHIP .......................................................... 65 SSD2123 Rev 0.30 P 2/66 Jan 2008 Solomon Systech TABLES TABLE 3-1 : ORDERING INFORMATION ..................................................................................................................................6 TABLE 5-1: SSD2123 BUMP DIE PAD COORDINATES (BUMP CENTRE) .................................................................................8 TABLE 6-1: POWER SUPPLY PINS .........................................................................................................................................15 TABLE 6-2: INTERFACE LOGIC PINS .....................................................................................................................................17 TABLE 6-3: INTERFACE LOGIC PINS .....................................................................................................................................18 TABLE 6-4: DRIVER OUTPUT PINS .......................................................................................................................................19 TABLE 6-5: MISCELLANEOUS PINS ......................................................................................................................................19 TABLE 7-1: COMMAND TABLE AND POR (POWER ON RESET) VALUES ...............................................................................20 SSD2123 Rev 0.30 P 3/66 Jan 2008 Solomon Systech FIGURES FIGURE 4-1 : BLOCK DIAGRAM ..............................................................................................................................................6 FIGURE 5-1 - DIE FLOOR PLAN (BUMP FACE UP) ...................................................................................................................7 FIGURE 8-1: LINE INVERSION AC DRIVER ...........................................................................................................................26 FIGURE 13-1: GATE AND SOURCE OUTPUT TIMING (LINE INVERSION)..................................................................................55 FIGURE 13-2- EXAMPLE OF COLOR FILTER ARRANGEMENT .................................................................................................56 FIGURE 13-3- PIXEL CLOCK TIMING ....................................................................................................................................57 FIGURE 13-4 COLOR MODE CONVERSION TIMING ...............................................................................................................58 FIGURE 13-5 VGH OUTPUT AGAINST SHUT & RESB ........................................................................................................59 FIGURE 13-6 - POWER UP SEQUENCE ..................................................................................................................................60 FIGURE 13-7 - POWER DOWN SEQUENCE .............................................................................................................................61 FIGURE 13-8 - SPI INTERFACE TIMING DIAGRAM & TRANSACTION EXAMPLE ....................................................................62 FIGURE 13-9 – 8-BIT SERIAL INTERFACE TIMING DIAGRAM & TRANSACTION EXAMPLE ....................................................63 FIGURE 13-10 – 24-BIT SERIAL INTERFACE TIMING DIAGRAM & TRANSACTION EXAMPLE ................................................64 FIGURE 14-1- LCD DRIVING VOLTAGE RELATIONSHIP .......................................................................................................65 SSD2123 Rev 0.30 P 4/66 Jan 2008 Solomon Systech 1 GENERAL DESCRIPTION SSD2123 is an all in one driver that integrated the power circuits, gate driver and source driver into single chip. It can drive a 16.7M/262k/8 color a-TFT panel with resolution of 480 x 272 RGB. SSD2123 embeds DC-DC Converter and Voltage generator to provide all necessary voltage required by the driver with minimum external components. A Common Voltage Generation Circuit is included to drive the TFT-display counter electrode. The driver supports three separated RGB Gamma settings. An Integrated Gamma Control Circuit is also included that can be adjusted by software commands to provide maximum flexibility and optimal display quality. SSD2123 can be operated down to 1.6V and provide different power save modes. It is suitable for any portable battery-driven applications requiring long operation period with compact size. 2 FEATURES • • • • • • • • • • • • • 480 x 272 RGB single chip controller driver IC for 16.7M/262k/8 color amorphous TFT LCD RGB color filter arrangement at Gate Power Supply - VDDIO = 1.6V – 3.6V (I/O Interface) - VCI = 2.5V – 3.6V (power supply for internal analog circuit) Output Voltages - Gate Driver: VGH-GND = 6V ~ 18V VGL-GND = -6V ~ -15V VGH-VGL = 32Vp-p - Source Driver: Source = VSS + 0.1 ~ AVDD - 0.1V Typical Source Output Voltage variation: ±30 mV - VCOM drive: VCOMH = 2.5V ~ 6.0V VCOML = 0V ~ -3.0V VCOM amplitude = 6V (max) VCOMH in ~10mV resolution steps System Interface - Serial Peripheral Interface (SPI), 3 wire (9bit), 4 wire and SPID 24 bit interface Video interface - 24-bit RGB interface (DEN, DOTCLK, HSYNC, VSYNC, RR[7:0], BB[7:0], GG[7:0]) - 18-bit RGB interface (DEN, DOTCLK, HSYNC, VSYNC, RR[7:2], BB[7:2], GG[7:2]) - 8-bit serial RGB interface - 6-bit serial RGB interface Support low power consumption: - Low voltage supply - Low current sleep mode - 8-color display mode for power saving - Charge sharing function for switching circuits - Software settable for Shut and 8 color modes. Internal power supply circuit - Voltage generator - DC-DC converter up to +18/-12 or +15/-15 (VGH - VGL < 32V) - AVDD generator of 2x, 2.5x or 3x of VCI Support separate RGB gamma control Support line / frame inversion TFT storage capacitance: Cs on common Support source and gate scan direction control Built-in Non Volatile Memory (OTP) for VCOM calibration SSD2123 Rev 0.30 P 5/66 Jan 2008 Solomon Systech 3 ORDERING INFORMATION Table 3-1 : Ordering Information Ordering Part Number SSD2123Z 4 Package Form COG BLOCK DIAGRAM Figure 4-1 : Block Diagram G0 to G815 VCOM S0 to S479 VCORE/VREGC/VDDIO Source driver Regulator Circuit SHUT CM VCI/VCIP CXN CXP C11N C11P C12N C12P C13N C13P C1N C1P C2N C2P C3N C3P Booster Circuit Gamma / Grayscale Voltage Generator Switches Network Data Latches Regulator Circuit VLCD Shift Registers VGH VGL Gate Driver Shift Registers Data Control Serial Interface SSD2123 Rev 0.30 P 6/66 Jan 2008 X400 STYPE[1,0] REV BGR SRGB RL VSYNC HSYNC DOTCLK DEN RR[7:0] GG[7:0] BB[7:0] SDO SDI SCL CS RES TB VSS/VSSRC/ AVSS/VCHS Solomon Systech 5 DIE PAD FLOOR PLAN Die Information: Pin 1627 Pin 1 23820 x 780 μm 304 ± 25μm 15 μm (Typ.) ≤ 2 μm within die 2 50 x 80 μm (IO pad, Pad 1-320) 70 μm 2 50 x 100 μm (Dummy pad, Pad 321322, 1626-1627) 53 μm 2 17 x 100 μm (G/S pad, Pad 323-1625) 18 μm Pad Pitch 2: Bump Size 3: Pad Pitch 3: Output Pad Pitch: 19 G10 36 G8 G4 G0 100 Dummy 25 G2 100 Dummy 67 18 G6 53 Die Center (0,0) 15 15 y 10 10 x : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : : 2 Die Size: Die Thickness: Bump Height: Bump Co-planarity: Bump Size 1: Pad Pitch 1: Bump Size 2: 25 25 25 25 Center: (-11785, 25) 2 Size: 75 x 75 μm 25 25 Center: (11785, 25) 2 Size: 75 x 75 μm 50 Pin 320 Pin 321 Rev 0.30 50 Center: (11785, -299) 2 Size: 50 x 50 μm Figure 5-1 - Die Floor Plan (Bump face up) * Diagram is not to scale SSD2123 50 Center: (-11785, -299) 2 Size: 50 x 50 μm P 7/66 Jan 2008 Solomon Systech Table 5-1: SSD2123 Bump Die Pad Coordinates (Bump Centre) Pad # 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 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 Signal X-pos Y-pos Pad # Signal X-pos Y-pos Pad # Signal X-pos Y-pos Pad # NC -11620 -299 65 VGH -7140 -299 129 C12N -2660 -299 193 NC -11550 -299 66 VGH -7070 -299 130 C12N -2590 -299 194 NC -11480 -299 67 VGH -7000 -299 131 C12N -2520 -299 195 NC -11410 -299 68 VGH -6930 -299 132 C12N -2450 -299 196 VSS -11340 -299 69 VGH -6860 -299 133 C12N -2380 -299 197 VSS -11270 -299 70 VCHS -6790 -299 134 C13P -2310 -299 198 VLCD255 -11200 -299 71 VCHS -6720 -299 135 C13P -2240 -299 199 VLCD255 -11130 -299 72 VCHS -6650 -299 136 C13P -2170 -299 200 VLCD255 -11060 -299 73 VCHS -6580 -299 137 C13P -2100 -299 201 VLCD255 -10990 -299 74 VCHS -6510 -299 138 C13N -2030 -299 202 VSSRC -10920 -299 75 VCHS -6440 -299 139 C13N -1960 -299 203 VSSRC -10850 -299 76 VCHS -6370 -299 140 C13N -1890 -299 204 VCIP -10780 -299 77 VCHS -6300 -299 141 C13N -1820 -299 205 VCIP -10710 -299 78 VCHS -6230 -299 142 CXP -1750 -299 206 TESTA -10640 -299 79 VCHS -6160 -299 143 CXP -1680 -299 207 TESTB -10570 -299 80 VCHS -6090 -299 144 CXP -1610 -299 208 VSS -10500 -299 81 VCHS -6020 -299 145 CXP -1540 -299 209 NC -10430 -299 82 VCHS -5950 -299 146 CXN -1470 -299 210 NC -10360 -299 83 AVDDJ -5880 -299 147 CXN -1400 -299 211 NC -10290 -299 84 AVDDJ -5810 -299 148 CXN -1330 -299 212 NC -10220 -299 85 AVDDJ -5740 -299 149 CXN -1260 -299 213 NC -10150 -299 86 AVDDJ -5670 -299 150 VCIM -1190 -299 214 NC -10080 -299 87 AVDDG -5600 -299 151 VCIM -1120 -299 215 AVSS -10010 -299 88 AVDDG -5530 -299 152 VCIM -1050 -299 216 AVSS -9940 -299 89 AVDDG -5460 -299 153 VCIM -980 -299 217 AVSS -9870 -299 90 AVDDG -5390 -299 154 VCOM -910 -299 218 AVSS -9800 -299 91 AVDD -299 155 VCOM -840 -299 219 -5320 VGL -9730 -299 92 AVDD -299 156 VCOM -770 -299 220 -5250 VGL -9660 -299 93 AVDD -299 157 VCOM -700 -299 221 -5180 VGL -9590 -299 94 AVDD -299 158 VCOM -630 -299 222 -5110 VGL -9520 -299 95 AVDD -299 159 VCOM -560 -299 223 -5040 VGL -9450 -299 96 AVDD -299 160 VCOM -490 -299 224 -4970 VGL -9380 -299 97 AVDD -299 161 VCOM -420 -299 225 -4900 C3P -9310 -299 98 AVDD -299 162 CSSRC -350 -299 226 -4830 C3P -9240 -299 99 AVDD -299 163 CSSRC -280 -299 227 -4760 C3P -9170 -299 100 C11P -4690 -299 164 CSSRC -210 -299 228 C3P -9100 -299 101 C11P -4620 -299 165 CSSRC -140 -299 229 C3P -9030 -299 102 C11P -4550 -299 166 CSSRC -70 -299 230 C3N -8960 -299 103 C11P -4480 -299 167 CSSRC 0 -299 231 C3N -8890 -299 104 C11P -4410 -299 168 VCHS 70 -299 232 C3N -8820 -299 105 C11P -4340 -299 169 VCHS 140 -299 233 C3N -8750 -299 106 C11N -4270 -299 170 VCHS 210 -299 234 C3N -8680 -299 107 C11N -4200 -299 171 VCHS 280 -299 235 C2P -8610 -299 108 C11N -4130 -299 172 VCHS 350 -299 236 C2P -8540 -299 109 C11N -4060 -299 173 VCHS 420 -299 237 C2P -8470 -299 110 C11N -3990 -299 174 VCOML 490 -299 238 C2P -8400 -299 111 C11N -3920 -299 175 VCOML 560 -299 239 C2N -8330 -299 112 VCI -3850 -299 176 VCOML 630 -299 240 C2N -8260 -299 113 VCI -3780 -299 177 VCOML 700 -299 241 C2N -8190 -299 114 VCI -3710 -299 178 VCOML 770 -299 242 C2N -8120 -299 115 VCI -3640 -299 179 VCOML 840 -299 243 C1P -8050 -299 116 VCI -3570 -299 180 VCOML 910 -299 244 C1P -7980 -299 117 VCI -3500 -299 181 VCOML 980 -299 245 C1P -7910 -299 118 VCI -3430 -299 182 VCOML 1050 -299 246 C1P -7840 -299 119 VCI -3360 -299 183 VCOML 1120 -299 247 C1N -7770 -299 120 VCI -3290 -299 184 VCOML 1190 -299 248 C1N -7700 -299 121 VCI -3220 -299 185 VCOMH 1260 -299 249 C1N -7630 -299 122 C12P -3150 -299 186 VCOMH 1330 -299 250 C1N -7560 -299 123 C12P -3080 -299 187 VCOMH 1400 -299 251 VGH -7490 -299 124 C12P -3010 -299 188 VCOMH 1470 -299 252 VGH -7420 -299 125 C12P -2940 -299 189 VCOMH 1540 -299 253 VGH -7350 -299 126 C12P -2870 -299 190 VCOMH 1610 -299 254 VGH -7280 -299 127 C12P -2800 -299 191 VCOMH 1680 -299 255 VGH -7210 -299 128 C12N -2730 -299 192 VCOMH 1750 -299 256 SSD2123 Rev 0.30 P 8/66 Jan 2008 Signal VCOMH VCOMH VCOMH NC AVSS AVSS AVSS AVSS VSS NC NC NC NC NC NC VSS NC NC NC NC NC VSS CSSRC CSSRC CSSRC AVSS AVSS VCI VCI VCI VCORE VCORE VCORE VCORE VREGC VREGC VREGC VREGC VSS VSS VSS VDDIO VDDIO VDDIO VDDIO B7 B6 B5 B4 B3 B2 B1 B0 VSS G7 G6 G5 G4 G3 G2 G1 G0 VSS R7 X-pos Y-pos 1820 -299 1890 -299 1960 -299 2030 -299 2100 -299 2170 -299 2240 -299 2310 -299 2380 -299 2450 -299 2520 -299 2590 -299 2660 -299 2730 -299 2800 -299 2870 -299 2940 -299 3010 -299 3080 -299 3150 -299 3220 -299 3290 -299 3360 -299 3430 -299 3500 -299 3570 -299 3640 -299 3710 -299 3780 -299 3850 -299 3920 -299 3990 -299 4060 -299 4130 -299 4200 -299 4270 -299 4340 -299 4410 -299 4480 -299 4550 -299 4620 -299 4690 -299 4760 -299 4830 -299 4900 -299 4970 -299 5040 -299 5110 -299 5180 -299 5250 -299 5320 -299 5390 -299 5460 -299 5530 -299 5600 -299 5670 -299 5740 -299 5810 -299 5880 -299 5950 -299 6020 -299 6090 -299 6160 -299 6230 -299 Solomon Systech Pad # 257 258 259 260 261 262 263 264 265 266 267 268 269 270 271 272 273 274 275 276 277 278 279 280 281 282 283 284 285 286 287 288 289 290 291 292 293 294 295 296 297 298 299 300 301 302 303 304 305 306 307 308 309 310 311 312 313 314 315 316 317 318 319 320 Signal X-pos Y-pos Pad # R6 6300 -299 321 R5 6370 -299 322 R4 6440 -299 323 R3 6510 -299 324 R2 6580 -299 325 R1 6650 -299 326 R0 6720 -299 327 VSS 6790 -299 328 DOTCLK 6860 -299 329 DOTCLK 6930 -299 330 VDDIO 7000 -299 331 HSYNC 7070 -299 332 VSS 7140 -299 333 VSYNC 7210 -299 334 VDDIO 7280 -299 335 DEN 7350 -299 336 VSS 7420 -299 337 SDC 7490 -299 338 SDI 7560 -299 339 SCK 7630 -299 340 CSB 7700 -299 341 SDO 7770 -299 342 VDDIO 7840 -299 343 GPI3 7910 -299 344 GPI2 7980 -299 345 GPI1 8050 -299 346 GPI0 8120 -299 347 STYPE1 8190 -299 348 STYPE0 8260 -299 349 CM 8330 -299 350 RESB 8400 -299 351 SPID 8470 -299 352 REV 8540 -299 353 BGR 8610 -299 354 TB 8680 -299 355 RL 8750 -299 356 SHUT 8820 -299 357 GAMAS 8890 -299 358 NC 8960 -299 359 SRGB 9030 -299 360 DENMODE 9100 -299 361 X400 9170 -299 362 VDDIO 9240 -299 363 AVSS 9310 -299 364 AVSS 9380 -299 365 AVSS 9450 -299 366 AVSS 9520 -299 367 VCI 9590 -299 368 VCI 9660 -299 369 VCI 9730 -299 370 VCI 9800 -299 371 NC 9870 -299 372 NC 9940 -299 373 NC 10010 -299 374 NC 10080 -299 375 NC 10150 -299 376 NC 10220 -299 377 NC 10290 -299 378 NC 10360 -299 379 NC 10430 -299 380 NC 10500 -299 381 NC 10570 -299 382 NC 10640 -299 383 NC 10710 -299 384 SSD2123 Rev 0.30 P 9/66 Signal X-pos Y-pos Pad # Signal NC 11821.5 157 385 G<125> NC 11768.5 282 386 G<127> G<1> 11718 157 387 G<129> G<3> 11700 282 388 G<131> G<5> 11682 157 389 G<133> G<7> 11664 282 390 G<135> G<9> 11646 157 391 G<137> G<11> 11628 282 392 G<139> G<13> 11610 157 393 G<141> G<15> 11592 282 394 G<143> G<17> 11574 157 395 G<145> G<19> 11556 282 396 G<147> G<21> 11538 157 397 G<149> G<23> 11520 282 398 G<151> G<25> 11502 157 399 G<153> G<27> 11484 282 400 G<155> G<29> 11466 157 401 G<157> G<31> 11448 282 402 G<159> G<33> 11430 157 403 G<161> G<35> 11412 282 404 G<163> G<37> 11394 157 405 G<165> G<39> 11376 282 406 G<167> G<41> 11358 157 407 G<169> G<43> 11340 282 408 G<171> G<45> 11322 157 409 G<173> G<47> 11304 282 410 G<175> G<49> 11286 157 411 G<177> G<51> 11268 282 412 G<179> G<53> 11250 157 413 G<181> G<55> 11232 282 414 G<183> G<57> 11214 157 415 G<185> G<59> 11196 282 416 G<187> G<61> 11178 157 417 G<189> G<63> 11160 282 418 G<191> G<65> 11142 157 419 G<193> G<67> 11124 282 420 G<195> G<69> 11106 157 421 G<197> G<71> 11088 282 422 G<199> G<73> 11070 157 423 G<201> G<75> 11052 282 424 G<203> G<77> 11034 157 425 G<205> G<79> 11016 282 426 G<207> G<81> 10998 157 427 G<209> G<83> 10980 282 428 G<211> G<85> 10962 157 429 G<213> G<87> 10944 282 430 G<215> G<89> 10926 157 431 G<217> G<91> 10908 282 432 G<219> G<93> 10890 157 433 G<221> G<95> 10872 282 434 G<223> G<97> 10854 157 435 G<225> G<99> 10836 282 436 G<227> G<101> 10818 157 437 G<229> G<103> 10800 282 438 G<231> G<105> 10782 157 439 G<233> G<107> 10764 282 440 G<235> G<109> 10746 157 441 G<237> G<111> 10728 282 442 G<239> G<113> 10710 157 443 G<241> G<115> 10692 282 444 G<243> G<117> 10674 157 445 G<245> G<119> 10656 282 446 G<247> G<121> 10638 157 447 G<249> G<123> 10620 282 448 G<251> Jan 2008 X-pos Y-pos Pad # 10602 157 449 10584 282 450 10566 157 451 10548 282 452 10530 157 453 10512 282 454 10494 157 455 10476 282 456 10458 157 457 10440 282 458 10422 157 459 10404 282 460 10386 157 461 10368 282 462 10350 157 463 10332 282 464 10314 157 465 10296 282 466 10278 157 467 10260 282 468 10242 157 469 10224 282 470 10206 157 471 10188 282 472 10170 157 473 10152 282 474 10134 157 475 10116 282 476 10098 157 477 10080 282 478 10062 157 479 10044 282 480 10026 157 481 10008 282 482 9990 157 483 9972 282 484 9954 157 485 9936 282 486 9918 157 487 9900 282 488 9882 157 489 9864 282 490 9846 157 491 9828 282 492 9810 157 493 9792 282 494 9774 157 495 9756 282 496 9738 157 497 9720 282 498 9702 157 499 9684 282 500 9666 157 501 9648 282 502 9630 157 503 9612 282 504 9594 157 505 9576 282 506 9558 157 507 9540 282 508 9522 157 509 9504 282 510 9486 157 511 9468 282 512 Signal G<253> G<255> G<257> G<259> G<261> G<263> G<265> G<267> G<269> G<271> G<273> G<275> G<277> G<279> G<281> G<283> G<285> G<287> G<289> G<291> G<293> G<295> G<297> G<299> G<301> G<303> G<305> G<307> G<309> G<311> G<313> G<315> G<317> G<319> G<321> G<323> G<325> G<327> G<329> G<331> G<333> G<335> G<337> G<339> G<341> G<343> G<345> G<347> G<349> G<351> G<353> G<355> G<357> G<359> G<361> G<363> G<365> G<367> G<369> G<371> G<373> G<375> G<377> G<379> X-pos Y-pos 9450 157 9432 282 9414 157 9396 282 9378 157 9360 282 9342 157 9324 282 9306 157 9288 282 9270 157 9252 282 9234 157 9216 282 9198 157 9180 282 9162 157 9144 282 9126 157 9108 282 9090 157 9072 282 9054 157 9036 282 9018 157 9000 282 8982 157 8964 282 8946 157 8928 282 8910 157 8892 282 8874 157 8856 282 8838 157 8820 282 8802 157 8784 282 8766 157 8748 282 8730 157 8712 282 8694 157 8676 282 8658 157 8640 282 8622 157 8604 282 8586 157 8568 282 8550 157 8532 282 8514 157 8496 282 8478 157 8460 282 8442 157 8424 282 8406 157 8388 282 8370 157 8352 282 8334 157 8316 282 Solomon Systech Pad # 513 514 515 516 517 518 519 520 521 522 523 524 525 526 527 528 529 530 531 532 533 534 535 536 537 538 539 540 541 542 543 544 545 546 547 548 549 550 551 552 553 554 555 556 557 558 559 560 561 562 563 564 565 566 567 568 569 570 571 572 573 574 575 576 577 Signal G<381> G<383> G<385> G<387> G<389> G<391> G<393> G<395> G<397> G<399> G<401> G<403> G<405> G<407> G<409> G<411> G<413> G<415> G<417> G<419> G<421> G<423> G<425> G<427> G<429> G<431> G<433> G<435> G<437> G<439> G<441> G<443> G<445> G<447> G<449> G<451> G<453> G<455> G<457> G<459> G<461> G<463> G<465> G<467> G<469> G<471> G<473> G<475> G<477> G<479> G<481> G<483> G<485> G<487> G<489> G<491> G<493> G<495> G<497> G<499> G<501> G<503> G<505> G<507> G<509> SSD2123 X-pos Y-pos Pad # 8298 157 578 8280 282 579 8262 157 580 8244 282 581 8226 157 582 8208 282 583 8190 157 584 8172 282 585 8154 157 586 8136 282 587 8118 157 588 8100 282 589 8082 157 590 8064 282 591 8046 157 592 8028 282 593 8010 157 594 7992 282 595 7974 157 596 7956 282 597 7938 157 598 7920 282 599 7902 157 600 7884 282 601 7866 157 602 7848 282 603 7830 157 604 7812 282 605 7794 157 606 7776 282 607 7758 157 608 7740 282 609 7722 157 610 7704 282 611 7686 157 612 7668 282 613 7650 157 614 7632 282 615 7614 157 616 7596 282 617 7578 157 618 7560 282 619 7542 157 620 7524 282 621 7506 157 622 7488 282 623 7470 157 624 7452 282 625 7434 157 626 7416 282 627 7398 157 628 7380 282 629 7362 157 630 7344 282 631 7326 157 632 7308 282 633 7290 157 634 7272 282 635 7254 157 636 7236 282 637 7218 157 638 7200 282 639 7182 157 640 7164 282 641 7146 157 642 Rev 0.30 P 10/66 Signal X-pos Y-pos Pad # Signal G<511> 7128 282 643 G<641> G<513> 7110 157 644 G<643> G<515> 7092 282 645 G<645> G<517> 7074 157 646 G<647> G<519> 7056 282 647 G<649> G<521> 7038 157 648 G<651> G<523> 7020 282 649 G<653> G<525> 7002 157 650 G<655> G<527> 6984 282 651 G<657> G<529> 6966 157 652 G<659> G<531> 6948 282 653 G<661> G<533> 6930 157 654 G<663> G<535> 6912 282 655 G<665> G<537> 6894 157 656 G<667> G<539> 6876 282 657 G<669> G<541> 6858 157 658 G<671> G<543> 6840 282 659 G<673> G<545> 6822 157 660 G<675> G<547> 6804 282 661 G<677> G<549> 6786 157 662 G<679> G<551> 6768 282 663 G<681> G<553> 6750 157 664 G<683> G<555> 6732 282 665 G<685> G<557> 6714 157 666 G<687> G<559> 6696 282 667 G<689> G<561> 6678 157 668 G<691> G<563> 6660 282 669 G<693> G<565> 6642 157 670 G<695> G<567> 6624 282 671 G<697> G<569> 6606 157 672 G<699> G<571> 6588 282 673 G<701> G<573> 6570 157 674 G<703> G<575> 6552 282 675 G<705> G<577> 6534 157 676 G<707> G<579> 6516 282 677 G<709> G<581> 6498 157 678 G<711> G<583> 6480 282 679 G<713> G<585> 6462 157 680 G<715> G<587> 6444 282 681 G<717> G<589> 6426 157 682 G<719> G<591> 6408 282 683 G<721> G<593> 6390 157 684 G<723> G<595> 6372 282 685 G<725> G<597> 6354 157 686 G<727> G<599> 6336 282 687 G<729> G<601> 6318 157 688 G<731> G<603> 6300 282 689 G<733> G<605> 6282 157 690 G<735> G<607> 6264 282 691 G<737> G<609> 6246 157 692 G<739> G<611> 6228 282 693 G<741> G<613> 6210 157 694 G<743> G<615> 6192 282 695 G<745> G<617> 6174 157 696 G<747> G<619> 6156 282 697 G<749> G<621> 6138 157 698 G<751> G<623> 6120 282 699 G<753> G<625> 6102 157 700 G<755> G<627> 6084 282 701 G<757> G<629> 6066 157 702 G<759> G<631> 6048 282 703 G<761> G<633> 6030 157 704 G<763> G<635> 6012 282 705 G<765> G<637> 5994 157 706 G<767> G<639> 5976 282 707 G<769> Jan 2008 X-pos Y-pos Pad # 5958 157 708 5940 282 709 5922 157 710 5904 282 711 5886 157 712 5868 282 713 5850 157 714 5832 282 715 5814 157 716 5796 282 717 5778 157 718 5760 282 719 5742 157 720 5724 282 721 5706 157 722 5688 282 723 5670 157 724 5652 282 725 5634 157 726 5616 282 727 5598 157 728 5580 282 729 5562 157 730 5544 282 731 5526 157 732 5508 282 733 5490 157 734 5472 282 735 5454 157 736 5436 282 737 5418 157 738 5400 282 739 5382 157 740 5364 282 741 5346 157 742 5328 282 743 5310 157 744 5292 282 745 5274 157 746 5256 282 747 5238 157 748 5220 282 749 5202 157 750 5184 282 751 5166 157 752 5148 282 753 5130 157 754 5112 282 755 5094 157 756 5076 282 757 5058 157 758 5040 282 759 5022 157 760 5004 282 761 4986 157 762 4968 282 763 4950 157 764 4932 282 765 4914 157 766 4896 282 767 4878 157 768 4860 282 769 4842 157 770 4824 282 771 4806 157 772 Signal G<771> G<773> G<775> G<777> G<779> G<781> G<783> G<785> G<787> G<789> G<791> G<793> G<795> G<797> G<799> G<801> G<803> G<805> G<807> G<809> G<811> G<813> G<815> DUMMY DUMMY DUMMY S<479> S<478> S<477> S<476> S<475> S<474> S<473> S<472> S<471> S<470> S<469> S<468> S<467> S<466> S<465> S<464> S<463> S<462> S<461> S<460> S<459> S<458> S<457> S<456> S<455> S<454> S<453> S<452> S<451> S<450> S<449> S<448> S<447> S<446> S<445> S<444> S<443> S<442> S<441> X-pos Y-pos 4788 282 4770 157 4752 282 4734 157 4716 282 4698 157 4680 282 4662 157 4644 282 4626 157 4608 282 4590 157 4572 282 4554 157 4536 282 4518 157 4500 282 4482 157 4464 282 4446 157 4428 282 4410 157 4392 282 4374 157 4356 282 4338 157 4320 282 4302 157 4284 282 4266 157 4248 282 4230 157 4212 282 4194 157 4176 282 4158 157 4140 282 4122 157 4104 282 4086 157 4068 282 4050 157 4032 282 4014 157 3996 282 3978 157 3960 282 3942 157 3924 282 3906 157 3888 282 3870 157 3852 282 3834 157 3816 282 3798 157 3780 282 3762 157 3744 282 3726 157 3708 282 3690 157 3672 282 3654 157 3636 282 Solomon Systech Pad # 773 774 775 776 777 778 779 780 781 782 783 784 785 786 787 788 789 790 791 792 793 794 795 796 797 798 799 800 801 802 803 804 805 806 807 808 809 810 811 812 813 814 815 816 817 818 819 820 821 822 823 824 825 826 827 828 829 830 831 832 833 834 835 836 837 Signal S<440> S<439> S<438> S<437> S<436> S<435> S<434> S<433> S<432> S<431> S<430> S<429> S<428> S<427> S<426> S<425> S<424> S<423> S<422> S<421> S<420> S<419> S<418> S<417> S<416> S<415> S<414> S<413> S<412> S<411> S<410> S<409> S<408> S<407> S<406> S<405> S<404> S<403> S<402> S<401> S<400> S<399> S<398> S<397> S<396> S<395> S<394> S<393> S<392> S<391> S<390> S<389> S<388> S<387> S<386> S<385> S<384> S<383> S<382> S<381> S<380> S<379> S<378> S<377> S<376> SSD2123 X-pos Y-pos Pad # 3618 157 838 3600 282 839 3582 157 840 3564 282 841 3546 157 842 3528 282 843 3510 157 844 3492 282 845 3474 157 846 3456 282 847 3438 157 848 3420 282 849 3402 157 850 3384 282 851 3366 157 852 3348 282 853 3330 157 854 3312 282 855 3294 157 856 3276 282 857 3258 157 858 3240 282 859 3222 157 860 3204 282 861 3186 157 862 3168 282 863 3150 157 864 3132 282 865 3114 157 866 3096 282 867 3078 157 868 3060 282 869 3042 157 870 3024 282 871 3006 157 872 2988 282 873 2970 157 874 2952 282 875 2934 157 876 2916 282 877 2898 157 878 2880 282 879 2862 157 880 2844 282 881 2826 157 882 2808 282 883 2790 157 884 2772 282 885 2754 157 886 2736 282 887 2718 157 888 2700 282 889 2682 157 890 2664 282 891 2646 157 892 2628 282 893 2610 157 894 2592 282 895 2574 157 896 2556 282 897 2538 157 898 2520 282 899 2502 157 900 2484 282 901 2466 157 902 Rev 0.30 P 11/66 Signal X-pos Y-pos Pad # Signal S<375> 2448 282 903 S<310> S<374> 2430 157 904 S<309> S<373> 2412 282 905 S<308> S<372> 2394 157 906 S<307> S<371> 2376 282 907 S<306> S<370> 2358 157 908 S<305> S<369> 2340 282 909 S<304> S<368> 2322 157 910 S<303> S<367> 2304 282 911 S<302> S<366> 2286 157 912 S<301> S<365> 2268 282 913 S<300> S<364> 2250 157 914 S<299> S<363> 2232 282 915 S<298> S<362> 2214 157 916 S<297> S<361> 2196 282 917 S<296> S<360> 2178 157 918 S<295> S<359> 2160 282 919 S<294> S<358> 2142 157 920 S<293> S<357> 2124 282 921 S<292> S<356> 2106 157 922 S<291> S<355> 2088 282 923 S<290> S<354> 2070 157 924 S<289> S<353> 2052 282 925 S<288> S<352> 2034 157 926 S<287> S<351> 2016 282 927 S<286> S<350> 1998 157 928 S<285> S<349> 1980 282 929 S<284> S<348> 1962 157 930 S<283> S<347> 1944 282 931 S<282> S<346> 1926 157 932 S<281> S<345> 1908 282 933 S<280> S<344> 1890 157 934 S<279> S<343> 1872 282 935 S<278> S<342> 1854 157 936 S<277> S<341> 1836 282 937 S<276> S<340> 1818 157 938 S<275> S<339> 1800 282 939 S<274> S<338> 1782 157 940 S<273> S<337> 1764 282 941 S<272> S<336> 1746 157 942 S<271> S<335> 1728 282 943 S<270> S<334> 1710 157 944 S<269> S<333> 1692 282 945 S<268> S<332> 1674 157 946 S<267> S<331> 1656 282 947 S<266> S<330> 1638 157 948 S<265> S<329> 1620 282 949 S<264> S<328> 1602 157 950 S<263> S<327> 1584 282 951 S<262> S<326> 1566 157 952 S<261> S<325> 1548 282 953 S<260> S<324> 1530 157 954 S<259> S<323> 1512 282 955 S<258> S<322> 1494 157 956 S<257> S<321> 1476 282 957 S<256> S<320> 1458 157 958 S<255> S<319> 1440 282 959 S<254> S<318> 1422 157 960 S<253> S<317> 1404 282 961 S<252> S<316> 1386 157 962 S<251> S<315> 1368 282 963 S<250> S<314> 1350 157 964 S<249> S<313> 1332 282 965 S<248> S<312> 1314 157 966 S<247> S<311> 1296 282 967 S<246> Jan 2008 X-pos Y-pos 1278 157 1260 282 1242 157 1224 282 1206 157 1188 282 1170 157 1152 282 1134 157 1116 282 1098 157 1080 282 1062 157 1044 282 1026 157 1008 282 990 157 972 282 954 157 936 282 918 157 900 282 882 157 864 282 846 157 828 282 810 157 792 282 774 157 756 282 738 157 720 282 702 157 684 282 666 157 648 282 630 157 612 282 594 157 576 282 558 157 540 282 522 157 504 282 486 157 468 282 450 157 432 282 414 157 396 282 378 157 360 282 342 157 324 282 306 157 288 282 270 157 252 282 234 157 216 282 198 157 180 282 162 157 144 282 126 157 Pad # 968 969 970 971 972 973 974 975 976 977 978 979 980 981 982 983 984 985 986 987 988 989 990 991 992 993 994 995 996 997 998 999 1000 1001 1002 1003 1004 1005 1006 1007 1008 1009 1010 1011 1012 1013 1014 1015 1016 1017 1018 1019 1020 1021 1022 1023 1024 1025 1026 1027 1028 1029 1030 1031 1032 Signal S<245> S<244> S<243> S<242> S<241> S<240> DUMMY S<239> S<238> S<237> S<236> S<235> S<234> S<233> S<232> S<231> S<230> S<229> S<228> S<227> S<226> S<225> S<224> S<223> S<222> S<221> S<220> S<219> S<218> S<217> S<216> S<215> S<214> S<213> S<212> S<211> S<210> S<209> S<208> S<207> S<206> S<205> S<204> S<203> S<202> S<201> S<200> S<199> S<198> S<197> S<196> S<195> S<194> S<193> S<192> S<191> S<190> S<189> S<188> S<187> S<186> S<185> S<184> S<183> S<182> X-pos Y-pos 108 282 90 157 72 282 54 157 36 282 18 157 0 282 -18 157 -36 282 -54 157 -72 282 -90 157 -108 282 -126 157 -144 282 -162 157 -180 282 -198 157 -216 282 -234 157 -252 282 -270 157 -288 282 -306 157 -324 282 -342 157 -360 282 -378 157 -396 282 -414 157 -432 282 -450 157 -468 282 -486 157 -504 282 -522 157 -540 282 -558 157 -576 282 -594 157 -612 282 -630 157 -648 282 -666 157 -684 282 -702 157 -720 282 -738 157 -756 282 -774 157 -792 282 -810 157 -828 282 -846 157 -864 282 -882 157 -900 282 -918 157 -936 282 -954 157 -972 282 -990 157 -1008 282 -1026 157 -1044 282 Solomon Systech Pad # 1033 1034 1035 1036 1037 1038 1039 1040 1041 1042 1043 1044 1045 1046 1047 1048 1049 1050 1051 1052 1053 1054 1055 1056 1057 1058 1059 1060 1061 1062 1063 1064 1065 1066 1067 1068 1069 1070 1071 1072 1073 1074 1075 1076 1077 1078 1079 1080 1081 1082 1083 1084 1085 1086 1087 1088 1089 1090 1091 1092 1093 1094 1095 1096 1097 Signal S<181> S<180> S<179> S<178> S<177> S<176> S<175> S<174> S<173> S<172> S<171> S<170> S<169> S<168> S<167> S<166> S<165> S<164> S<163> S<162> S<161> S<160> S<159> S<158> S<157> S<156> S<155> S<154> S<153> S<152> S<151> S<150> S<149> S<148> S<147> S<146> S<145> S<144> S<143> S<142> S<141> S<140> S<139> S<138> S<137> S<136> S<135> S<134> S<133> S<132> S<131> S<130> S<129> S<128> S<127> S<126> S<125> S<124> S<123> S<122> S<121> S<120> S<119> S<118> S<117> SSD2123 X-pos Y-pos Pad # -1062 157 1098 -1080 282 1099 -1098 157 1100 -1116 282 1101 -1134 157 1102 -1152 282 1103 -1170 157 1104 -1188 282 1105 -1206 157 1106 -1224 282 1107 -1242 157 1108 -1260 282 1109 -1278 157 1110 -1296 282 1111 -1314 157 1112 -1332 282 1113 -1350 157 1114 -1368 282 1115 -1386 157 1116 -1404 282 1117 -1422 157 1118 -1440 282 1119 -1458 157 1120 -1476 282 1121 -1494 157 1122 -1512 282 1123 -1530 157 1124 -1548 282 1125 -1566 157 1126 -1584 282 1127 -1602 157 1128 -1620 282 1129 -1638 157 1130 -1656 282 1131 -1674 157 1132 -1692 282 1133 -1710 157 1134 -1728 282 1135 -1746 157 1136 -1764 282 1137 -1782 157 1138 -1800 282 1139 -1818 157 1140 -1836 282 1141 -1854 157 1142 -1872 282 1143 -1890 157 1144 -1908 282 1145 -1926 157 1146 -1944 282 1147 -1962 157 1148 -1980 282 1149 -1998 157 1150 -2016 282 1151 -2034 157 1152 -2052 282 1153 -2070 157 1154 -2088 282 1155 -2106 157 1156 -2124 282 1157 -2142 157 1158 -2160 282 1159 -2178 157 1160 -2196 282 1161 -2214 157 1162 Rev 0.30 P 12/66 Signal X-pos Y-pos Pad # Signal X-pos Y-pos S<116> -2232 282 1163 S<51> -3402 157 S<115> -2250 157 1164 S<50> -3420 282 S<114> -2268 282 1165 S<49> -3438 157 S<113> -2286 157 1166 S<48> -3456 282 S<112> -2304 282 1167 S<47> -3474 157 S<111> -2322 157 1168 S<46> -3492 282 S<110> -2340 282 1169 S<45> -3510 157 S<109> -2358 157 1170 S<44> -3528 282 S<108> -2376 282 1171 S<43> -3546 157 S<107> -2394 157 1172 S<42> -3564 282 S<106> -2412 282 1173 S<41> -3582 157 S<105> -2430 157 1174 S<40> -3600 282 S<104> -2448 282 1175 S<39> -3618 157 S<103> -2466 157 1176 S<38> -3636 282 S<102> -2484 282 1177 S<37> -3654 157 S<101> -2502 157 1178 S<36> -3672 282 S<100> -2520 282 1179 S<35> -3690 157 S<99> -2538 157 1180 S<34> -3708 282 S<98> -2556 282 1181 S<33> -3726 157 S<97> -2574 157 1182 S<32> -3744 282 S<96> -2592 282 1183 S<31> -3762 157 S<95> -2610 157 1184 S<30> -3780 282 S<94> -2628 282 1185 S<29> -3798 157 S<93> -2646 157 1186 S<28> -3816 282 S<92> -2664 282 1187 S<27> -3834 157 S<91> -2682 157 1188 S<26> -3852 282 S<90> -2700 282 1189 S<25> -3870 157 S<89> -2718 157 1190 S<24> -3888 282 S<88> -2736 282 1191 S<23> -3906 157 S<87> -2754 157 1192 S<22> -3924 282 S<86> -2772 282 1193 S<21> -3942 157 S<85> -2790 157 1194 S<20> -3960 282 S<84> -2808 282 1195 S<19> -3978 157 S<83> -2826 157 1196 S<18> -3996 282 S<82> -2844 282 1197 S<17> -4014 157 S<81> -2862 157 1198 S<16> -4032 282 S<80> -2880 282 1199 S<15> -4050 157 S<79> -2898 157 1200 S<14> -4068 282 S<78> -2916 282 1201 S<13> -4086 157 S<77> -2934 157 1202 S<12> -4104 282 S<76> -2952 282 1203 S<11> -4122 157 S<75> -2970 157 1204 S<10> -4140 282 S<74> -2988 282 1205 S<9> -4158 157 S<73> -3006 157 1206 S<8> -4176 282 S<72> -3024 282 1207 S<7> -4194 157 S<71> -3042 157 1208 S<6> -4212 282 S<70> -3060 282 1209 S<5> -4230 157 S<69> -3078 157 1210 S<4> -4248 282 S<68> -3096 282 1211 S<3> -4266 157 S<67> -3114 157 1212 S<2> -4284 282 S<66> -3132 282 1213 S<1> -4302 157 S<65> -3150 157 1214 S<0> -4320 282 S<64> -3168 282 1215 DUMMY -4338 157 S<63> -3186 157 1216 DUMMY -4356 282 S<62> -3204 282 1217 DUMMY -4374 157 S<61> -3222 157 1218 G<814> -4392 282 S<60> -3240 282 1219 G<812> -4410 157 S<59> -3258 157 1220 G<810> -4428 282 S<58> -3276 282 1221 G<808> -4446 157 S<57> -3294 157 1222 G<806> -4464 282 S<56> -3312 282 1223 G<804> -4482 157 S<55> -3330 157 1224 G<802> -4500 282 S<54> -3348 282 1225 G<800> -4518 157 S<53> -3366 157 1226 G<798> -4536 282 S<52> -3384 282 1227 G<796> -4554 157 Jan 2008 Pad # 1228 1229 1230 1231 1232 1233 1234 1235 1236 1237 1238 1239 1240 1241 1242 1243 1244 1245 1246 1247 1248 1249 1250 1251 1252 1253 1254 1255 1256 1257 1258 1259 1260 1261 1262 1263 1264 1265 1266 1267 1268 1269 1270 1271 1272 1273 1274 1275 1276 1277 1278 1279 1280 1281 1282 1283 1284 1285 1286 1287 1288 1289 1290 1291 1292 Signal G<794> G<792> G<790> G<788> G<786> G<784> G<782> G<780> G<778> G<776> G<774> G<772> G<770> G<768> G<766> G<764> G<762> G<760> G<758> G<756> G<754> G<752> G<750> G<748> G<746> G<744> G<742> G<740> G<738> G<736> G<734> G<732> G<730> G<728> G<726> G<724> G<722> G<720> G<718> G<716> G<714> G<712> G<710> G<708> G<706> G<704> G<702> G<700> G<698> G<696> G<694> G<692> G<690> G<688> G<686> G<684> G<682> G<680> G<678> G<676> G<674> G<672> G<670> G<668> G<666> X-pos Y-pos -4572 282 -4590 157 -4608 282 -4626 157 -4644 282 -4662 157 -4680 282 -4698 157 -4716 282 -4734 157 -4752 282 -4770 157 -4788 282 -4806 157 -4824 282 -4842 157 -4860 282 -4878 157 -4896 282 -4914 157 -4932 282 -4950 157 -4968 282 -4986 157 -5004 282 -5022 157 -5040 282 -5058 157 -5076 282 -5094 157 -5112 282 -5130 157 -5148 282 -5166 157 -5184 282 -5202 157 -5220 282 -5238 157 -5256 282 -5274 157 -5292 282 -5310 157 -5328 282 -5346 157 -5364 282 -5382 157 -5400 282 -5418 157 -5436 282 -5454 157 -5472 282 -5490 157 -5508 282 -5526 157 -5544 282 -5562 157 -5580 282 -5598 157 -5616 282 -5634 157 -5652 282 -5670 157 -5688 282 -5706 157 -5724 282 Solomon Systech Pad # 1293 1294 1295 1296 1297 1298 1299 1300 1301 1302 1303 1304 1305 1306 1307 1308 1309 1310 1311 1312 1313 1314 1315 1316 1317 1318 1319 1320 1321 1322 1323 1324 1325 1326 1327 1328 1329 1330 1331 1332 1333 1334 1335 1336 1337 1338 1339 1340 1341 1342 1343 1344 1345 1346 1347 1348 1349 1350 1351 1352 1353 1354 1355 1356 1357 Signal G<664> G<662> G<660> G<658> G<656> G<654> G<652> G<650> G<648> G<646> G<644> G<642> G<640> G<638> G<636> G<634> G<632> G<630> G<628> G<626> G<624> G<622> G<620> G<618> G<616> G<614> G<612> G<610> G<608> G<606> G<604> G<602> G<600> G<598> G<596> G<594> G<592> G<590> G<588> G<586> G<584> G<582> G<580> G<578> G<576> G<574> G<572> G<570> G<568> G<566> G<564> G<562> G<560> G<558> G<556> G<554> G<552> G<550> G<548> G<546> G<544> G<542> G<540> G<538> G<536> SSD2123 X-pos Y-pos Pad # -5742 157 1358 -5760 282 1359 -5778 157 1360 -5796 282 1361 -5814 157 1362 -5832 282 1363 -5850 157 1364 -5868 282 1365 -5886 157 1366 -5904 282 1367 -5922 157 1368 -5940 282 1369 -5958 157 1370 -5976 282 1371 -5994 157 1372 -6012 282 1373 -6030 157 1374 -6048 282 1375 -6066 157 1376 -6084 282 1377 -6102 157 1378 -6120 282 1379 -6138 157 1380 -6156 282 1381 -6174 157 1382 -6192 282 1383 -6210 157 1384 -6228 282 1385 -6246 157 1386 -6264 282 1387 -6282 157 1388 -6300 282 1389 -6318 157 1390 -6336 282 1391 -6354 157 1392 -6372 282 1393 -6390 157 1394 -6408 282 1395 -6426 157 1396 -6444 282 1397 -6462 157 1398 -6480 282 1399 -6498 157 1400 -6516 282 1401 -6534 157 1402 -6552 282 1403 -6570 157 1404 -6588 282 1405 -6606 157 1406 -6624 282 1407 -6642 157 1408 -6660 282 1409 -6678 157 1410 -6696 282 1411 -6714 157 1412 -6732 282 1413 -6750 157 1414 -6768 282 1415 -6786 157 1416 -6804 282 1417 -6822 157 1418 -6840 282 1419 -6858 157 1420 -6876 282 1421 -6894 157 1422 Rev 0.30 P 13/66 Signal X-pos Y-pos Pad # Signal G<534> -6912 282 1423 G<404> G<532> -6930 157 1424 G<402> G<530> -6948 282 1425 G<400> G<528> -6966 157 1426 G<398> G<526> -6984 282 1427 G<396> G<524> -7002 157 1428 G<394> G<522> -7020 282 1429 G<392> G<520> -7038 157 1430 G<390> G<518> -7056 282 1431 G<388> G<516> -7074 157 1432 G<386> G<514> -7092 282 1433 G<384> G<512> -7110 157 1434 G<382> G<510> -7128 282 1435 G<380> G<508> -7146 157 1436 G<378> G<506> -7164 282 1437 G<376> G<504> -7182 157 1438 G<374> G<502> -7200 282 1439 G<372> G<500> -7218 157 1440 G<370> G<498> -7236 282 1441 G<368> G<496> -7254 157 1442 G<366> G<494> -7272 282 1443 G<364> G<492> -7290 157 1444 G<362> G<490> -7308 282 1445 G<360> G<488> -7326 157 1446 G<358> G<486> -7344 282 1447 G<356> G<484> -7362 157 1448 G<354> G<482> -7380 282 1449 G<352> G<480> -7398 157 1450 G<350> G<478> -7416 282 1451 G<348> G<476> -7434 157 1452 G<346> G<474> -7452 282 1453 G<344> G<472> -7470 157 1454 G<342> G<470> -7488 282 1455 G<340> G<468> -7506 157 1456 G<338> G<466> -7524 282 1457 G<336> G<464> -7542 157 1458 G<334> G<462> -7560 282 1459 G<332> G<460> -7578 157 1460 G<330> G<458> -7596 282 1461 G<328> G<456> -7614 157 1462 G<326> G<454> -7632 282 1463 G<324> G<452> -7650 157 1464 G<322> G<450> -7668 282 1465 G<320> G<448> -7686 157 1466 G<318> G<446> -7704 282 1467 G<316> G<444> -7722 157 1468 G<314> G<442> -7740 282 1469 G<312> G<440> -7758 157 1470 G<310> G<438> -7776 282 1471 G<308> G<436> -7794 157 1472 G<306> G<434> -7812 282 1473 G<304> G<432> -7830 157 1474 G<302> G<430> -7848 282 1475 G<300> G<428> -7866 157 1476 G<298> G<426> -7884 282 1477 G<296> G<424> -7902 157 1478 G<294> G<422> -7920 282 1479 G<292> G<420> -7938 157 1480 G<290> G<418> -7956 282 1481 G<288> G<416> -7974 157 1482 G<286> G<414> -7992 282 1483 G<284> G<412> -8010 157 1484 G<282> G<410> -8028 282 1485 G<280> G<408> -8046 157 1486 G<278> G<406> -8064 282 1487 G<276> Jan 2008 X-pos Y-pos -8082 157 -8100 282 -8118 157 -8136 282 -8154 157 -8172 282 -8190 157 -8208 282 -8226 157 -8244 282 -8262 157 -8280 282 -8298 157 -8316 282 -8334 157 -8352 282 -8370 157 -8388 282 -8406 157 -8424 282 -8442 157 -8460 282 -8478 157 -8496 282 -8514 157 -8532 282 -8550 157 -8568 282 -8586 157 -8604 282 -8622 157 -8640 282 -8658 157 -8676 282 -8694 157 -8712 282 -8730 157 -8748 282 -8766 157 -8784 282 -8802 157 -8820 282 -8838 157 -8856 282 -8874 157 -8892 282 -8910 157 -8928 282 -8946 157 -8964 282 -8982 157 -9000 282 -9018 157 -9036 282 -9054 157 -9072 282 -9090 157 -9108 282 -9126 157 -9144 282 -9162 157 -9180 282 -9198 157 -9216 282 -9234 157 Pad # 1488 1489 1490 1491 1492 1493 1494 1495 1496 1497 1498 1499 1500 1501 1502 1503 1504 1505 1506 1507 1508 1509 1510 1511 1512 1513 1514 1515 1516 1517 1518 1519 1520 1521 1522 1523 1524 1525 1526 1527 1528 1529 1530 1531 1532 1533 1534 1535 1536 1537 1538 1539 1540 1541 1542 1543 1544 1545 1546 1547 1548 1549 1550 1551 1552 Signal G<274> G<272> G<270> G<268> G<266> G<264> G<262> G<260> G<258> G<256> G<254> G<252> G<250> G<248> G<246> G<244> G<242> G<240> G<238> G<236> G<234> G<232> G<230> G<228> G<226> G<224> G<222> G<220> G<218> G<216> G<214> G<212> G<210> G<208> G<206> G<204> G<202> G<200> G<198> G<196> G<194> G<192> G<190> G<188> G<186> G<184> G<182> G<180> G<178> G<176> G<174> G<172> G<170> G<168> G<166> G<164> G<162> G<160> G<158> G<156> G<154> G<152> G<150> G<148> G<146> X-pos Y-pos -9252 282 -9270 157 -9288 282 -9306 157 -9324 282 -9342 157 -9360 282 -9378 157 -9396 282 -9414 157 -9432 282 -9450 157 -9468 282 -9486 157 -9504 282 -9522 157 -9540 282 -9558 157 -9576 282 -9594 157 -9612 282 -9630 157 -9648 282 -9666 157 -9684 282 -9702 157 -9720 282 -9738 157 -9756 282 -9774 157 -9792 282 -9810 157 -9828 282 -9846 157 -9864 282 -9882 157 -9900 282 -9918 157 -9936 282 -9954 157 -9972 282 -9990 157 -10008 282 -10026 157 -10044 282 -10062 157 -10080 282 -10098 157 -10116 282 -10134 157 -10152 282 -10170 157 -10188 282 -10206 157 -10224 282 -10242 157 -10260 282 -10278 157 -10296 282 -10314 157 -10332 282 -10350 157 -10368 282 -10386 157 -10404 282 Solomon Systech Pad # 1553 1554 1555 1556 1557 1558 1559 1560 1561 1562 1563 1564 1565 1566 1567 1568 1569 1570 1571 1572 1573 1574 1575 1576 1577 1578 1579 1580 1581 1582 1583 1584 1585 1586 1587 1588 1589 1590 1591 1592 1593 1594 1595 1596 1597 1598 1599 1600 1601 1602 1603 1604 1605 1606 1607 1608 1609 1610 1611 1612 1613 1614 1615 1616 1617 Signal G<144> G<142> G<140> G<138> G<136> G<134> G<132> G<130> G<128> G<126> G<124> G<122> G<120> G<118> G<116> G<114> G<112> G<110> G<108> G<106> G<104> G<102> G<100> G<98> G<96> G<94> G<92> G<90> G<88> G<86> G<84> G<82> G<80> G<78> G<76> G<74> G<72> G<70> G<68> G<66> G<64> G<62> G<60> G<58> G<56> G<54> G<52> G<50> G<48> G<46> G<44> G<42> G<40> G<38> G<36> G<34> G<32> G<30> G<28> G<26> G<24> G<22> G<20> G<18> G<16> X-pos Y-pos Pad # -10422 157 1618 -10440 282 1619 -10458 157 1620 -10476 282 1621 -10494 157 1622 -10512 282 1623 -10530 157 1624 -10548 282 1625 -10566 157 1626 -10584 282 1627 -10602 157 -10620 282 -10638 157 -10656 282 -10674 157 -10692 282 -10710 157 -10728 282 -10746 157 -10764 282 -10782 157 -10800 282 -10818 157 -10836 282 -10854 157 -10872 282 -10890 157 -10908 282 -10926 157 -10944 282 -10962 157 -10980 282 -10998 157 -11016 282 -11034 157 -11052 282 -11070 157 -11088 282 -11106 157 -11124 282 -11142 157 -11160 282 -11178 157 -11196 282 -11214 157 -11232 282 -11250 157 -11268 282 -11286 157 -11304 282 -11322 157 -11340 282 -11358 157 -11376 282 -11394 157 -11412 282 -11430 157 -11448 282 -11466 157 -11484 282 -11502 157 -11520 282 -11538 157 -11556 282 -11574 157 Signal G<14> G<12> G<10> G<8> G<6> G<4> G<2> G<0> NC NC X-pos Y-pos Pad # -11592 282 -11610 157 -11628 282 -11646 157 -11664 282 -11682 157 -11700 282 -11718 157 -11768.5 282 -11821.5 157 Signal X-pos Y-pos Pad # Signal X-pos Y-pos Note: IC material Temperature expansion factor should take into account during panel design. SSD2123 Rev 0.30 P 14/66 Jan 2008 Solomon Systech 6 Pin Description SSD2123 Pin Function Description Key: I = Input O =Output I/O = Bi-directional (input/output) P = Power pin GND = System VSS Table 6-1: Power Supply Pins Name Type VSS AVSS VSSRC P Connect to GND GND GND VCHS GND VCORE VREGC VDDEXT System VDD P VDDIO System VDD VCI Power supply P VCIP VCIM VCI O AVDD AVDDJ O AVDDG VCOMH O VCOML VLCD255 VGH O VGL VCOMR SSD2123 I Stabilizing capacitor Stabilizing capacitor AVDD on FPC AVDD on FPC Stabilizing capacitor Stabilizing capacitor Stabilizing capacitor Function P 15/66 When not in use - System ground pin of the IC. Grounding for analog circuit. Ground of Grounding for analog circuit. This pin requires a Power noise free path for providing accurate LCD driving Supply voltages. Grounding for booster circuit. Power for VDD for core use Core - Connect a capacitor for stabilization Logic Power for Voltage input pin for internal logic. Internal Connect to System VDD VCORE (refer to power connection Figure 14-1) Regulator Power for Voltage input pin for logic I/O. Interface Logic Pins Booster input voltage pin. Power for - Connect to voltage source between 2.5V to 3.6V Analog Voltage supply pin for analog circuit. This pin Circuits requires a noise free path for providing accurate LCD driving voltages. Booster Negative voltage of VCI Output Booster Booster voltage and regulated between 5.1V to 6.1V. Voltages Controlled by command Power control 2 (R0Ch) Voltage power supply used by on chip analog blocks and for analog VGH/VGL dcdc. Must connect AVDD together Voltage power supply used by on chip analog blocks and for analog VGH/VGL dcdc. Must connect AVDD together This pin indicates a HIGH level of VCOM generated Voltages in driving the VCOM alternation. for VCOM This pin indicates a LOW level of VCOM generated in Signal driving the VCOM alternation. LCD Stabilizing Driving capacitor Voltages Stabilizing capacitor External voltage External source or Reference Open Rev 0.30 Description Jan 2008 This pin is the maximum source driver voltage. - A positive power output pin for gate driver. - A negative power output pin for gate driver. - This pin provides voltage reference for internal voltage regulator when register VDV[4:0] of Power Open Control 4 is set to “01111”. Solomon Systech VREGC CXP CXN C11P C11N C12P C12N C13P C13N C1P C1N C2P C2N C3P C3N CSSRC SSD2123 P P Regulator Stabilizing output for logic capacitor circuits Booster capacitor Booster capacitor Booster capacitor Booster Booster and capacitor Stabilizati Booster on capacitor Capacitors Booster capacitor Booster capacitor Charge Sharing Rev 0.30 P 16/66 Jan 2008 Regulator output for VCORE use - - Connect a capacitor to CXN - Connect a capacitor to CXP - Connect a capacitor to C11N - Connect a capacitor to C11P - Connect a capacitor to C12N - Connect a capacitor to C12P - Connect a capacitor to C13N - Connect a capacitor to C13P - Connect a capacitor to C1N - Connect a capacitor to C1P - Connect a capacitor to C2N - Connect a capacitor to C2P - Connect a capacitor to C3N - Connect a capacitor to C3P - - Connect a capacitor to VSS Open - Solomon Systech Table 6-2: Interface Logic Pins Name SPID CSB SDI SDC SCK SDO SHUT Typ Connect to Function Description e ID selection pin for the SPI serial interface. When sending serial data, the “ID” bit must match with the logic stage of VDDIO or this pin. VSS (Refer to Serial Interface block description on Page XX Serial for details) I Interface MPU Chip select pin of serial interface. MPU Data input pin in serial mode. MPU Data/Command pin of serial interface. MPU Clock input pin in serial mode. Serial O MPU Data output pin in serial mode. Interface Display shut down pin to put the driver into sleep mode. A sharp falling edge must be provided to such pin when IC VDDIO or Logic power on. I Control VSS - Connect to VDDIO for sleep mode - Connect to VSS for normal operating mode Note: Software can override the setting When not in use VDDIO VSS VSS VSS Open VDDIO or VSS Frame synchronization signal. Fixed to VDDIO or VSS if not used. VSYNC I MPU HSYNC I MPU DOTCLK I MPU DEN I MPU Display enable pin from controller. VDDIO MPU Graphic Display Data - RR[7:0] : - RR[7:2] : - GG[7:0] : - GG[7:2] : - BB[7:0] : - BB[7:2] : VDDIO or VSS System reset RGB Interface Display Timing Signals RR[7:0] GG[7:0] I BB[7:0] RESB I MPU SRGB I VDDIO VSS or X400 I VDDIO VSS or DENMODE I VDDIO VSS or SSD2123 Rev 0.30 RGB interface selection RGB interface selection RGB interface selection P 17/66 Line synchronization signal. Fixed to VDDIO or VSS if not used Dot-clock signal and oscillator source. External clock must be provided to that pin even at front or black porch non-display period. Red Data – 24bit parallel/8bit serial Red Data –18bit parallel/6bit serial Green Data –24bit parallel Green Data –18bit parallel Blue Data –24bit parallel Blue Data –18bit parallel System reset pin. Initialization occurs once this pin is pulled Low, the minimum pulse length is 1ms. A low pulse must be applied after power-on. Connect this pin to VDDIO when not used. Determine data input for SSD2123. - Connect to VSS for the operation of parallel RGB mode 18/24 bits. - Connect to VDDIO for the operation of serial RGB mode 6/8 bits. Note: Software can override the setting Determine data input for SSD2123. - Connect to VSS for the operation of using full 480 sources - Connect to VDDIO for the operation of using 400 sources at center. First data will appear at S40. Note: Software can override the setting Determine data input for SSD2123. - Connect to VSS for the operation of SYNC mode - Connect to VDDIO for the operation of DEN mode Note: Software can override the setting Jan 2008 VDDIO - - - Solomon Systech GPI[3:0] I User define GAMAS I VDDIO VSS or Logic Control General propose pins defined by user Open (GPIP=VSS) GAMAS controls the default register values VDDIO or VSS Table 6-3: Interface Logic Pins Name Type STYPE0 I STYPE1 I BGR I Connect to Function Description VDDIO VSS VDDIO VSS or STYPE[1:0] = 0x ; SPID type 3 wires SPI STYPE[1:0] = 10 ; standard 3 wires SPI STYPE[1:0] = 11 ; standard 4 wires SPI VDDIO VSS or Serial Interface or Selection I VDDIO VSS or RL I VDDIO VSS or Panel Mapping controls TB I VDDIO VSS or SSD2123 I VDDIO VSS Rev 0.30 - Input pin to select the display reversion. - Connect to VDDIO mapping data “0” to maximum pixel voltage for normal white panel - Connect to VSS mapping data “0” to minimum pixel voltage for normal black panel Note: Software can override the setting Select the Source driver data shift direction. - Connect to VDDIO for display first pixel data at S0 - Connect to VSS for display first pixel data at S479 Note: Software can override the setting Select the Gate driver scan direction. Note: Software can override the setting Jan 2008 or VDDIO VSS or VDDIO VSS or VDDIO VSS or Input pin to select 16.7M-color or 8-color display mode. After entered 8-color display mode, the driver will switch to Frame-Inversion-Mode, and only MSB VDDIO of the data Red, Green and Blue will be considered. VSS - Connect to VDDIO for 8-color display mode - Connect to VSS for 16.7M-color display mode Note: Software can override the setting or P 18/66 - Color mapping selection pin. Refer to G0-G815 pin VDDIO description. VSS Note: Software can override the setting REV CM When not in use or Solomon Systech Table 6-4: Driver Output Pins Name Type VCOM G0-G815 O Description LCD A power supply for the TFT-display common electrode. Gate driver output pins. These pins output VGH or VGL level. Color filter arrangement depends on BGR pin. Open G(3n): Display Red if BGR = Low, Blue if BGR = High. G(3n+1): Display Green. G(3n+2): Display Blue if BGR = Low, Red if BGR = High. Source driver output pins. Open LCD S0-S479 When not in use Open Connect to Function LCD Driving Signals LCD Table 6-5: Miscellaneous Pins Name Type Connect to Function NC - - DUMMY - - TESTA/B/C I/O SSD2123 FPC Rev 0.30 Description When not in use These pins must be left open and cannot be connected Open together Floating pins and no connection inside the IC. These pins Open can be shorted together or connect to any signal. Test pin of the internal circuit. IC Testing - Leave this pin open and optional to insert test point in FPC Open Signal for evaluation. - P 19/66 Jan 2008 Solomon Systech 7 COMMAND TABLE Table 7-1: Command Table and POR (Power On Reset) values Reg# Register Index R R01h Driver output control ([XXXX][X0X1]0Fh ) R02h LCD-DrivingWaveform Control (0C02h) R/W D/C IB15 IB14 IB13 IB12 IB11 IB10 IB9 IB8 IB7 IB6 IB5 IB4 IB3 IB2 IB1 IB0 0 0 * * * * * * * * * ID6 ID5 ID4 ID3 ID2 ID1 ID0 0 1 X400 RL REV CAD BGR SM TB 1 0 0 1 1 1 1 1 1 X X X X X 0 X 1 0 0 1 1 1 1 1 1 0 0 0 B/C EOR NW9 NW8 NW7 NW6 NW5 NW4 NW3 NW2 NW1 NW0 0 0 1 0 0 0 0 0 1 1 0 0 0 0 0 0 0 0 1 R03h Power control (1) (E4E2h) 0 1 DCT3 DCT2 DCT1 DCT0 BT3 BT2 BT1 BT0 DC3 DC2 DC1 DC0 AP2 AP1 AP0 0 1 1 1 0 0 1 0 0 1 1 1 0 0 0 1 0 R04h Separate Gamma(1) (0400h) 0 0 0 0 0 0 OLO 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 0 R0Bh Frame cycle control (DC00h) 0 NO1 NO0 SDT1 SDT0 EQ1 EQ0 0 0 EQ2 0 0 0 BTP1 BTP0 0 0 1 1 0 1 1 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 VRC2 VRC1 VRC0 1 1 Power control (2) R0Ch (0005h) 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 1 Power control (3) R0Dh (0002h) 0 1 0 0 0 0 0 0 0 0 0 0 0 0 VRH3 VRH2 VRH1 VRH0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 Power control (4) R0Eh (2900h) 0 1 0 0 VCOMG VDV4 VDV3 VDV2 VDV1 VDV0 0 0 0 0 0 0 0 VCOMAS 0 0 1 0 1 0 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 SCN8 SCN7 SCN6 SCN5 SCN4 SCN3 SCN2 SCN1 SCN0 R0Fh Gate scan starting Position (0000h) R16h R17h 0 1 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Pixel per line (EF8Eh) x400=0 (C786h) x400=1 0 1 XL8 XL7 XL6 XL5 XL4 XL3 XL2 XL1 XL0 HBP6 HBP5 HBP4 HBP3 1 1 1 0 1 1 1 1 0 0 0 0 1 1 1 0 0 0 1 1 1 1 0 0 0 1 Vertical Porch (0003h) 0 1 0 0 0 0 0 0 0 0 VBP7 VBP6 VBP5 VBP4 VBP3 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 0 1 0 0 0 0 0 0 nOTP 0 VCM7 VCM6 VCM5 VCM4 VCM3 VCM2 VCM1 VCM0 0 0 0 0 0 0 0 0 0 0 1 0 1 0 0 0 0 1 0 0 0 0 0 PKP 12 PKP 11 PKP 10 0 0 0 0 0 PKP 02 PKP 01 PKP 00 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 PKP 32 PKP 31 PKP 30 0 0 0 0 0 PKP 22 PKP 21 PKP 20 0 0 0 0 0 1 1 1 0 0 0 0 0 1 1 1 PKP 51 PKP 50 PKP 42 PKP 41 PKP 40 Power control (5) R1Eh (0029h) R30h R31h R32h R33h R34h R35h R36h R37h R3Ah R3Bh R28h γ control (1) (0000h) γ control (1) (0707h) γ control (1) 0 1 (0003h) γ control (1) 0 1 0 VBP2 VBP1 VBP0 0 0 0 0 0 PKP 52 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 PRP 12 PRP 11 PRP 10 0 0 0 0 0 PRP 02 PRP 01 PRP 00 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 1 1 0 0 0 0 0 PKN 12 PKN 11 PKN 10 0 0 0 0 0 PKN 02 PKN 01 PKN 00 0 0 0 0 0 0 1 1 0 0 0 0 0 1 1 1 PKN 31 PKN 30 PKN 22 PKN 21 PKN 20 0 1 0 0 0 0 0 PKN 32 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 PKN 52 PKN 51 PKN 50 0 0 0 0 0 PKN 42 PKN 41 PKN 40 0 1 0 0 0 0 0 0 1 1 1 0 0 0 0 0 1 1 1 0 1 0 0 0 0 0 PRN 12 PRN 11 PRN 10 0 0 0 0 0 PRN 02 PRN 01 PRN 00 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 VRP 13 VRP 12 VRP 11 VRP 10 VRP 03 VRP 02 VRP 01 VRP 00 (0204h) γ control (2) 1 1 0 (0707h) γ control (1) 1 0 (0000h) γ control (1) 0 HBP0 1 (0307h) γ control (1) 0 HBP1 0 (0401h) γ control (1) 0 HBP2 0 1 (0D0Bh) 0 0 0 VRP 14 0 0 0 0 0 0 0 0 1 1 0 1 0 0 0 0 1 0 1 1 0 0 VRN 14 VRN 13 VRN 12 VRN 11 VRN 10 0 0 0 0 VRN 03 VRN 02 VRN 01 VRN 00 γ control (2) 0 1 0 (0D0Bh) VCOM OTP (0000h) 0 0 0 0 1 1 0 1 0 0 0 0 1 0 1 1 0 1 0 0 0 0 0 0 0 0 0 0 0 0 CCB3 CCB2 CCB1 CCB0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 Note: X means hardware defining default setting SSD2123 Rev 0.30 P 20/66 Jan 2008 Solomon Systech Table 7-2 – Gamma Registers POR value Command R30h-R3Bh PKP0 PKP1 PKP2 PKP3 PKP4 PKP5 PRP0 PRP1 VRP0 VRP1 PKN0 PKN1 PKN2 PKN3 PKN4 PKN5 PRN0 PRN1 VRN0 VRN1 SSD2123 Rev 0.30 P 21/66 Jan 2008 GAMAS=0 GAMAS=1 000 000 111 111 011 000 001 100 1011 01101 111 011 000 000 111 111 100 010 1011 01101 000 000 000 010 001 000 000 111 0000 00111 101 100 010 010 111 111 110 000 0011 00000 Solomon Systech Table 7-3: Registers POR value at GAMAS = 0 Reg# R03h R0Ch R0Dh R0Eh R1Eh Register Power control (1) Power control (2) Power control (3) Power control (4) Power control (5) Hex code E4E2 0005 0002 2900 0029 IB15 IB14 IB13 IB12 IB11 IB10 IB9 1 0 0 0 0 1 0 0 0 0 1 0 0 1 0 0 0 0 0 0 0 0 0 1 0 1 0 0 0 0 0 0 0 0 0 IB8 0 0 0 1 0 IB7 IB6 1 0 0 0 0 1 0 0 0 0 IB5 1 0 0 0 1 IB4 IB3 0 0 0 0 0 0 0 0 0 1 IB2 0 1 0 0 0 IB1 IB0 1 0 1 0 0 0 1 0 0 1 Table 7-4: Registers POR value at GAMAS = 1 Reg# R03h R0Ch R0Dh R0Eh R1Eh Register Power control (1) Power control (2) Power control (3) Power control (4) Power control (5) SSD2123 Rev 0.30 Hex code E4E2 0005 000F 3100 0034 IB15 IB14 IB13 IB12 IB11 IB10 IB9 P 22/66 1 0 0 0 0 1 0 0 0 0 1 0 0 1 0 Jan 2008 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 0 0 0 IB8 0 0 0 1 0 IB7 IB6 1 0 0 0 0 1 0 0 0 0 IB5 1 0 0 0 1 IB4 IB3 0 0 0 0 1 0 0 1 0 0 IB2 0 1 1 0 1 IB1 IB0 1 0 1 0 0 0 1 1 0 0 Solomon Systech 8 COMMAND DESCRIPTION Index (IR) R/W W DC 0 IB15 ∗ IB14 ∗ IB13 ∗ IB12 ∗ IB11 ∗ IB10 ∗ IB9 ∗ IB8 ∗ IB7 ∗ IB6 ID6 IB5 ID5 IB4 ID4 IB3 ID3 IB2 ID2 IB1 ID1 IB0 ID0 The index instruction specifies the RAM control indexes (R00h to R7Fh). It sets the register number in the range of 0000000 to 1111111 in binary form. But do not access to Index register and instruction bits which do not have it’s own index register. Driver Output Control (R01h) (POR = [XXXX][X0X1]0Fh) R/W DC W 1 POR IB15 X400 X IB14 RL X IB13 REV X IB12 CAD X IB11 BGR X IB10 SM 0 IB9 TB X IB8 IB7 IB6 IB5 IB4 IB3 IB2 IB1 IB0 MUX8 MUX7 MUX6 MUX5 MUX4 MUX3 MUX2 MUX1 MUX0 1 0 0 0 0 1 1 1 1 X400: When X400=”0”, full 480 sources are in operation When X400=”1”, only 400 sources at the center are in operation. First data will appear at S40. X400 = 0 X400 = 1 G0 G2 G4 G1 G3 G5 G717 G719 G716 G718 S479 G0 G2 G4 G1 G3 G5 G717 G719 S0 G716 G718 S439 S40 RL: For MOD = “0”, selects the output shift direction of the source driver of stripe type. When RL = “1”, S0 shifts to S480 and 1st pixel color is assigned from S1. When RL = “0”, S480 shifts to S0 and 1st pixel color is assigned from S480. Set RL bit and BGR bit when changing the dot order of R, G and B. REV: Displays all character and graphics display sections with reversal when REV = “1”. Since the grayscale level can be reversed, display of the same data is enabled on normally white and normally black panels. Source output level is indicated below. REV RGB data 000000B : 111111B 000000B : 111111B 1 0 Source Output level VCOM = ”H” V63 : V0 V0 : V63 VCOM = ”L” V0 : V63 V63 : V0 CAD: Set up based on the retention capacitor configuration of the TFT panel. CAD 0 1 Retention capacitor configuration Cs on Common Cs on Gate BGR: For MOD = “0”, selects the <R><G><B> arrangement. When BGR = “0” <R><G><B> color is assigned from G0. When BGR = “1” <B><G><R> color is assigned from G0. SSD2123 Rev 0.30 P 23/66 Jan 2008 Solomon Systech SM: For MOD = “0”, change the division of gate driver. When SM = “0”, odd/even division (interlace mode) is selected. When SM = “1”, upper/lower division is selected. Select the division mode according to the mounting method. TB: For MOD = “0”, selects the output shift direction of the gate driver. When TB = “1”, G0 shifts to G815. When TB = “0”, G815 shifts to G0. Note: The default setting of register bits X400, RL, REV, BGR and TB are defined by the logic stage of corresponding hardware pins. These bits will override the hardware setting once software command was sent to set the bits. SSD2123 Rev 0.30 P 24/66 Jan 2008 Solomon Systech SM = 0 SM = 1 G0 G2 G4 G1 G3 G5 G812 G814 TB = 1 RL = 0 G1 G3 G812 G814 G813 G815 S479 TB = 0 RL = 0 G0 G2 G813 G815 S0 S479 S0 G0 G2 G0 G2 G4 G1 G3 G5 G812 G814 G1 G3 G812 G814 G813 G815 S479 TB = 1 RL = 1 G813 G815 S479 S0 S0 G0 G2 G0 G2 G4 G1 G3 G5 G812 G814 G1 G3 G812 G814 G813 G815 S479 TB = 0 RL = 1 G813 G815 S479 S0 S0 G0 G2 G4 G1 G3 G5 G0 G2 G812 G814 G1 G3 G812 G814 G813 G815 S479 SSD2123 Rev 0.30 S0 P 25/66 Jan 2008 G813 G815 S479 S0 Solomon Systech LCD-Driving-Waveform Control (R02h) (POR = 0C02h) R/W DC W 1 POR IB15 0 0 IB14 0 0 IB13 0 0 IB12 0 0 IB11 B/C 1 IB10 EOR 1 IB9 IB8 IB7 NW9 NW8 NW7 0 0 0 IB6 NW6 0 IB5 NW5 0 IB4 NW4 0 IB3 NW3 0 IB2 NW2 0 IB1 NW1 1 IB0 NW0 0 B/C: Select the liquid crystal drive waveform VCOM. When B/C = 0, frame inversion of the LCD driving signal is enabled. When B/C = 1, a N-line inversion waveform is generated and alternates in a N-line equals to NW[9:0]+1. EOR: When B/C = 1 and EOR = 1, the odd/even frame-select signals and the N-line inversion signals are EORed for alternating drive. EOR is used when the LCD is not alternated by combining the set values of the lines of the LCD driven and the N-lines. NW9-0: Specify the number of lines that will alternate at the N-line inversion setting (B/C = 1). NW9-0 alternate for every set value + 1 lines. Figure 8-1: Line Inversion AC Driver N Frame Back porch 1 2 3 N+1 Frame Front porch 4 820 821 5 822 823 Back porch 824 1 2 3 4 Front porch 5 820 821 822 823 824 Frame Inversion 816 line drive N Frame Back porch 1 2 3 N+1 Frame Front porch 4 820 821 5 822 823 Back porch 824 1 2 3 4 Front porch 5 820 821 822 823 Line Inversion 816 line drive SSD2123 Rev 0.30 P 26/66 Jan 2008 Solomon Systech Power control 1 (R03h) (POR = E3E2h) R/W DC W 1 POR IB15 IB14 IB13 IB12 IB11 DCT3 DCT2 DCT1 DCT0 BT3 1 1 1 0 0 IB10 BT2 0 IB9 BT1 1 IB8 BT0 1 IB7 DC3 1 IB6 DC2 1 IB5 DC1 1 IB4 DC0 0 IB3 AP2 0 IB2 AP1 0 IB1 AP0 1 IB0 0 0 DCT3-0: Set the step-up cycle of the step-up circuit for 8-color mode (CM = VDDIO). When the cycle is accelerated, the driving ability of the step-up circuit increases, but its current consumption increases too. Adjust the cycle taking into account the display quality and power consumption. For 512 dotclk per line DCT3 DCT2 DCT1 DCT0 0 0 0 0 0 0 1 0 0 1 0 0 0 1 1 0 1 0 0 0 1 0 1 1 1 0 0 1 1 1 0 1 1 1 1 0 1 1 1 1 Step-up cycle Fline × 8 Fline × 6 Fline × 5 Fline × 4 Fline × 2 Fline × 1 fosc / 1 fosc / 2 fosc / 4 fosc / 8 For 416 dotclk per line DCT3 DCT2 DCT1 DCT0 Step-up cycle 0 0 0 1 Fline × 8 0 0 1 1 Fline × 6 0 1 0 1 Fline × 5 0 1 1 1 Fline × 4 1 0 0 1 Fline × 2 1 0 1 1 Fline × 1 1 0 0 fosc / 1 1 1 1 0 1 fosc / 2 1 1 1 0 fosc / 4 1 1 1 1 fosc / 8 Note: Fline = Horizontal frequency (fH Typ. TBDkHz) fosc = DOTCLK frequency (fDOTCLK Typ. TBDMHz) BT3-0: Control the step-up factor of the step-up circuit. Adjust the step-up factor according to the power-supply voltage to be used. BT3 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 1 SSD2123 BT2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 1 BT1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 1 Rev 0.30 BT0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 1 P 27/66 VGH output VGL output AVDD x 3 -(VGH - VCI) AVDD x 3 -(VGH - AVDD) AVDD x 3 -(AVDD x 3) AVDD x 2 + VCI -(VGH) AVDD x 2 + VCI -(VGH - VCI) AVDD x 2 + VCI -(VGH - AVDD x 2) AVDD x 2 -(VGH) AVDD x 2 -(VGH - VCI) Reserved Reserved AVDD x 3 -(AVDD) Reserved Reserved Reserved Reserved Reserved Jan 2008 VGH booster ratio VGL booster ratio +6 -5 +6 -4 +6 -6 +5 -5 +5 -4 +5 -3 +4 -4 +4 -3 Reserved Reserved +6 -2 Reserved Reserved Reserved Reserved Reserved Solomon Systech DC3-0: Set the step-up cycle of the step-up circuit for 16.7M-color mode (CM = VSS). When the cycle is accelerated, the driving ability of the step-up circuit increases, but its current consumption increases too. Adjust the cycle taking into account the display quality and power consumption. For 512 dotclk per line DC3 0 DC2 0 0 0 0 0 1 1 1 1 0 0 1 1 1 1 1 1 1 1 DC1 0 1 0 1 0 1 0 0 1 1 DC0 0 0 0 0 0 1 0 1 0 1 Step-up cycle Fline × 8 Fline × 6 Fline × 5 Fline × 4 Fline × 2 Fline × 1 fosc / 1 fosc / 2 fosc / 4 fosc / 8 For 416 dotclk per line DC3 0 0 0 0 1 1 DC2 DC1 DC0 Step-up cycle 0 0 1 Fline × 8 0 1 1 Fline × 6 1 0 1 Fline × 5 1 1 1 Fline × 4 0 0 1 Fline × 2 0 1 1 Fline × 1 1 0 0 fosc / 1 1 0 1 fosc / 2 1 1 0 fosc / 4 1 1 1 fosc / 8 Fline = Horizontal frequency (fH Typ. TBDkHz) fosc = DOTCLK frequency (fDOTCLK Typ. TBDMHz) 1 1 1 1 Note: AP2-0: Adjust the amount of current from the stable-current source in the internal operational amplifier circuit. When the amount of current becomes large, the driving ability of the operational-amplifier circuits increase. Adjust the current taking into account the power consumption. While there is no display, such as the system is in a sleep mode, AP2-0 can be set to (0,0,0) and shutting down the operational amplifier can reduce the power consumption. AP2 0 0 0 0 1 1 1 1 AP1 0 0 1 1 0 0 1 1 AP0 0 1 0 1 0 1 0 1 Op-amp power Least Small Small to medium Medium Medium to large Large Large to Maximum Maximum Seperate Gamma (R04h) (POR = 0400h) R/W DC W 1 POR IB15 0 0 IB14 0 0 IB13 0 0 IB12 0 0 IB11 0 0 IB10 OLO 1 IB9 0 0 IB8 0 0 IB7 0 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 0 0 IB2 0 0 IB1 0 0 IB0 0 0 OLO: When OLO = “1”, all R,G and B gamma registers are set by one set of gamma control, R30h to R3Bh. When OLO = “0”, R, G and B gamma registers are set separately by registers R30h to R3Bh, R40h to R4Bh and R50h to R5Bh. SSD2123 Rev 0.30 P 28/66 Jan 2008 Solomon Systech Frame Cycle Control (R0Bh) (POR = D800h) R/W DC W 1 POR IB15 NO1 1 IB14 IB13 IB12 IB11 NO0 SDT1 SDT0 EQ1 1 0 1 1 IB10 EQ0 0 IB9 0 0 IB8 0 0 IB7 EQ2 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 IB2 BTP1 BTP0 0 0 IB1 0 0 IB0 0 0 NO1-0: Sets amount of non-overlap of the gate output. NO1 0 0 1 1 NO0 0 Amount of non-overlap HSYNC_falling + 100 DOTCLK HSYNC _falling + 60 DOTCLK HSYNC _falling + 30 DOTCLK 6 DOTCLK after Source On 1 0 1 1 Line period 1 Line period Gn Non-overlap period Gn+1 SDT1-0: Set delay amount from the gate output signal falling edge of the source outputs. SDT1 0 0 1 1 SDT0 0 Delay amount of the source output HSYNC_falling – 3 DOTCLK HSYNC_falling – 7 DOTCLK HSYNC_falling – 11 DOTCLK HSYNC_falling – 15 DOTCLK 1 0 1 EQ2-0: Sets the equalizing period on source EQ2 0 0 0 0 1 1 1 1 EQ1 0 0 1 1 0 0 1 1 EQ0 0 1 0 1 0 1 0 1 1 Line period EQ period No EQ 16 clock cycle 32 clock cycle Reserved 48 clock cycle 64 clock cycle 80 clock cycle 96 clock cycle 1 Line period Gn Sn EQ Delay amount of the source output Equalizing period BTP1-0: Set the Primary booster ratio. BTP1 0 0 1 1 SSD2123 Rev 0.30 P 29/66 BTP0 0 1 0 1 Jan 2008 Primary booster ratio 2X 2.5X 3X 2X Solomon Systech Power Control 2 (R0Ch) (POR = 0005h) R/W DC W 1 POR IB15 0 0 IB14 0 0 IB13 0 0 IB12 0 0 IB11 0 0 IB10 0 0 IB9 0 0 IB8 0 0 IB7 0 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 0 0 IB2 IB1 IB0 VRC2 VRC1 VRC0 1 0 1 VRC[2:0]: Adjust AVDD output voltage. The adjusted level is indicated in the chart below VRC2-0 setting. VRC2 0 0 VRC1 0 0 1 1 0 0 1 1 0 0 1 1 1 1 Note: VRC0 0 1 AVDD voltage 5.1V 5.3V 5.5V 5.7V 5.9V 6.1V Reserved Reserved 0 1 0 1 0 1 VCI=3.3V and without panel loading Figures on the above table are target AVDD output, actual AVDD voltage depends on VCI, booster efficiency and panel loading Power Control 3 (R0Dh) (POR = 000Ch) R/W DC W 1 POR IB15 IB14 IB13 IB12 0 0 0 0 0 0 0 0 IB11 0 0 IB10 0 0 IB9 0 0 IB8 0 0 IB7 0 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 IB2 IB1 IB0 VRH3 VRH2 VRH1 VRH0 1 1 0 0 VRH3-0: Set amplitude magnification of VLCD255. These bits amplify the VLCD255 voltage 1.78 to 3.00 times the Vref voltage set by VRH3-0. VRH3 VRH2 VRH1 VRH0 VLCD255 Voltage 0 0 0 0 Vref x 2.815 0 0 0 1 Vref x 2.905 0 0 0 Vref x 3.000 1 0 0 1 Vref x 1.780 1 0 1 0 Vref x 1.850 0 0 1 1 Vref x 1.930 0 0 1 0 Vref x 2.020 1 0 1 1 Vref x 2.090 1 1 0 0 Vref x 2.165 0 1 0 1 Vref x 2.245 0 1 0 0 Vref x 2.335 1 1 0 1 Vref x 2.400 1 1 1 0 Vref x 2.500 0 1 1 1 Vref x 2.570 0 1 1 1 0 Vref x 2.645 1 1 1 1 Vref x 2.725 Note: Vref is the internal reference voltage equals to 2.0V. SSD2123 Rev 0.30 P 30/66 Jan 2008 Solomon Systech Power Control 4 (R0Eh) (POR = 3200h) R/W DC W 1 POR IB15 IB14 IB13 IB12 IB11 IB10 IB9 IB8 IB7 0 0 VCOMG VDV4 VDV3 VDV2 VDV1 VDV0 0 0 0 1 1 0 0 1 0 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 0 0 IB2 0 0 IB1 IB0 0 VCOMAS 0 0 VCOMG: When VCOMG = “1”, it is possible to set output voltage of VCOML to any level, and the instruction (VDV4-0) becomes available. When VCOMG = “0”, VCOML output is fixed to Hi-z level, VCI2 output for VCOML power supply stops, and the instruction (VDV4-0) becomes unavailable. Set VCOMG according to the sequence of power supply setting flow as it relates with power supply operating sequence. VDV4-0: Set the alternating amplitudes of VCOM at the VCOM alternating drive. These bits amplify VCOM amplitude 0.6 to 1.23 times the VLCD255 voltage. When VCOMG = “0”, the settings become invalid. VDV4 0 0 0 VDV3 0 0 0 VDV1 0 0 1 1 VDV2 0 0 0 : : : 1 1 0 0 1 1 0 0 1 1 1 1 1 1 0 0 0 0 : : : 1 1 1 ∗ 0 0 0 1 VLCD255 x 1.05 VLCD255x 1.08 1 0 1 ∗ : Step = 0.03 : VLCD255 x 1.20 VLCD255 x 1.23 Reserved Reserved 1 1 1 1 Note1: Note2: Note3: 1 0 0 0 0 1 0 1 1 ∗ VCOMA < 6.0V VCOMH – VCOML < 6.0V |VCOML| < VCI VCOMAS: Set the equation of VCOML. VCOML = α VCOMAS 0 1 SSD2123 Rev 0.30 P 31/66 Jan 2008 VDV0 0 1 0 VCOMA VLCD255 x 0.60 VLCD255 x 0.63 VLCD255 x 0.66 : Step = 0.03 : VLCD255 x 0.99 VLCD255 x 1.02 External Voltage Reference x VCOMH - VCOMA α 1.0 0.667 Solomon Systech Pixel per line (R16h) (POR = 8F8Eh when x400=0, POR = C786h when x400=1 R/W DC IB15 IB14 IB13 IB12 IB11 IB10 IB9 IB8 IB7 IB6 IB5 IB4 IB3 IB2 IB1 IB0 W 1 XL8 XL7 XL6 XL5 XL4 XL3 XL2 XL1 XL0 HBP6 HBP5 HBP4 HBP3 HBP2 HBP1 HBP0 POR(x400=0) 1 1 1 0 1 1 1 1 1 0 0 0 1 1 1 0 POR(x400=1) 1 1 0 0 0 1 1 1 1 0 0 0 1 1 1 0 Note: Number of dotclk for hsync active low period must be smaller than that of HBP Only for 24-bit, 18-bit parallel and 8-bit, 6-bit serial interface. XL8-0: Set the number of valid pixel per line. XL8 0 0 0 XL7 0 0 0 XL6 0 0 0 XL5 0 0 1 1 1 1 0 0 0 0 1 1 1 1 1 1 1 1 1 0 0 0 1 XL4 0 0 0 : : : 0 0 : : : 1 1 ∗ XL3 0 0 0 XL2 0 0 0 XL1 0 0 1 XL0 0 1 0 1 1 1 1 1 1 0 1 1 1 ∗ 1 1 ∗ 1 1 ∗ 0 1 ∗ No. of pixel per line 1 2 3 : Step = 1 : 399 400 (por if x400=1) : Step = 1 : 479 480 (por if x400=0) Reserved HBP6-0: Set the delay period from falling edge of HSYNC signal to first valid data. No. of clock cycle of DOTCLK HBP6 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 HBP5 HBP4 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 HBP3 0 0 0 0 0 0 0 0 1 1 1 1 1 1 1 HBP2 0 0 0 0 1 1 1 1 0 0 0 0 1 1 1 HBP1 0 0 1 1 0 0 1 1 0 0 1 1 0 0 1 HBP0 0 1 0 1 0 1 0 1 0 1 0 1 0 1 0 : : : 1 1 SSD2123 1 1 Rev 0.30 1 1 1 P 32/66 1 1 Jan 2008 1 1 0 1 24-bit RGB 8-bit RGB (without dummy) 2 6 3 4 5 6 7 8 (por if x400=1) 9 10 11 12 13 14 15 16 (por if x400=0) 9 12 15 18 21 24 27 30 33 36 39 42 45 48 : Step = 1 : :Step = 3 128 129 384 387 Solomon Systech Example for 24-bit RGB interface: Cycle time of HYSYNC Set by HBP6-0 Set by XL8-0 HYSNC Pixel Data HFP Default 480 pixels per line Dummy D0 D1 D2 Dummy D477 D478 D479 DOTCLK 8 clock cycles of DOTCLK HBP6-0 = 000110 Example for 8-bit RGB interface (without dummy): Cycle time of HYSYNC Set by HBP5-0 Set by XL8-0 HYSNC Pixel Data HFP Default 480 pixels per line Dummy D0 D479 Dummy DOTCLK 24 clock cycles of DOTCLK HBP5-0 = 000110 SSD2123 Rev 0.30 P 33/66 Jan 2008 Solomon Systech Vertical Porch (R17h) (POR = 0003h) R/W DC W 1 POR IB15 IB14 IB13 IB12 IB11 0 0 0 0 0 0 0 0 0 0 IB10 0 0 IB9 0 0 IB8 0 0 IB7 IB6 IB5 IB4 IB3 IB2 IB1 IB0 VBP7 VBP6 VBP5 VBP4 VBP3 VBP2 VBP1 VBP0 0 0 0 0 0 0 1 1 VBP7-0: Set the delay period from falling edge of VSYNC to first valid line. The line data within this delay period will be treated as dummy line. VBP7 VBP6 VBP5 VBP4 VBP3 VBP2 VBP1 VBP0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 0 1 0 0 0 0 0 0 1 0 0 0 0 0 0 0 1 1 0 0 0 0 0 1 0 0 : : : 1 1 1 0 0 0 0 0 1 1 1 0 0 0 0 1 1 1 1 1 * * * * No. of clock cycle of HSYNC 0 1 2 3 4 : Step = 1 : 224 225 Reserved Example for 24-bit RGB interface: Cycle time of VSYNC Set by VBP7-0 VSYNC 272Lines HSYNC Dummy Lines SSD2123 Rev 0.30 st 1 Line P 34/66 Jan 2008 Last Line VFP Solomon Systech Power Control 5 (R1Eh) (POR = 0029h) R/W DC W 1 POR IB15 IB14 IB13 IB12 IB11 0 0 0 0 0 0 0 0 0 0 IB10 0 0 IB9 nOTP 0 IB8 IB7 IB6 IB5 IB4 IB3 IB2 IB1 IB0 0 VCM7 VCM6 VCM5 VCM4 VCM3 VCM2 VCM1 VCM0 0 0 0 1 0 1 0 0 1 nOTP: nOTP equals to “0” after power on reset and VCOMH voltage equals to programmed OTP value. When nOTP set to “1”, setting of VCM7-0 becomes valid and voltage of VCOMH can be adjusted. VCM7-0: Set the VCOMH voltage if nOTP = “1”. These bits amplify the VCOMH voltage 0.503 to 0.999 times the VLCD255 voltage. VCM7 0 0 VCM6 0 0 VCM5 0 0 VCM4 0 0 VCM3 0 0 VCM2 0 0 VCM1 0 0 VCM0 0 1 1 1 1 1 1 1 0 1 : : : 1 1 SSD2123 1 1 1 1 1 1 Note: VCI < VCOMH < AVDD Rev 0.30 P 35/66 Jan 2008 VCOMH VLCD255 x 0.503 VLCD255 x 0.505 : Step = 1/512 : VLCD255 x 0.997 VLCD255 x 0.999 Solomon Systech 9 EXTENDED COMMAND DESCRIPTION Reminder – In order to activate extended command, user is required to send R28h-0006 prioir to the extended command in application. See below for further description on the R28h register. VCOM OTP (R28h) (POR = 0000h) R/W DC W 1 POR IB15 0 0 IB14 0 0 IB13 0 0 IB12 0 0 IB11 0 0 IB10 0 0 IB9 0 0 IB8 0 0 IB7 0 0 IB6 0 0 IB5 0 0 IB4 0 0 IB3 IB2 IB1 IB0 CCB3 CCB2 CCB1 CCB0 0 0 0 0 CCB3-0: Command Control Bit, the master control of the internal command decoder. This register provides function of software reset and OTP programming. CCB3 0 0 CCB2 0 1 CCB1 0 0 CCB0 0 1 0 1 1 0 1 1 SSD2123 0 1 1 1 All other setting Rev 0.30 P 36/66 0 0 Jan 2008 Usage Release Reset or no action Driver initialization Enable extended test command/ Enable for OTP Programming Fire OTP Reset all command bits to default Reserved Solomon Systech 10 MTP PROGRAMMING/ ERASE MTP Programming sequence Remark: * The application setup should be synchronized. Note1: nMTP must set to “0” to activate the MTP effect. Note2: VCI is suggested to be larger than 3.3V during fire MTP. Precaution: 1. All capacitors on MTP machine should be discharged completely before placing the LCD module. 2. The MTP programming voltage should not be applied when placing and removing the LCD module. 3. The MTP programming voltage should not be applied before VDDIO/VDDEXT/VCI. 4. After MTP is finished, the capacitors at VGH and VCIX2 must be discharged completely before removing the LCD module. Figure 10-1: MTP programming circuitry Apply voltage at Step (4) SSD2123 VGH + C - Note: C = 1uF (built-in on the module) 14.5V ±0.1V GND SSD2123 Rev 0.30 P 37/66 Jan 2008 Solomon Systech Figure 10-2: MTP Programming Flowchart MTP Sequence Power up the module as application [e.g. VCI = 3.3V, VDDIO = 1.8V]* Turn on the display as normal mode to 65k/262k color with a testing pattern if any Set nMTP = “1” in R1Eh Not optimum value Adjust VCOMH by VCM[7:0] in R1Eh Optimized VCOMH value Toggle reset pin – Reset SSD2123 Connect a power supply to the module [VCI = VDDEXT = VDDIO = 3.3V]* Write commands for MTP initialization: Register Value R28h 0006h R29h 80C0h R2Dh 7F50h Wait 200ms for activation Connect VGH with 14.5V power supply (Figure 10-3) Write the optimum value to VCM [7:0] in R1Eh and set nMTP = “1”. Write command for firing MTP: Register Value R28h 000Ah Wait 500ms for the process Power down the module and remove 14.5V power supply MTP completed SSD2123 Rev 0.30 P 38/66 Jan 2008 Solomon Systech MTP Erase sequence Remark: * The application setup should be synchronized. Precaution: 1. All capacitors on MTP machine should be discharged completely before placing the LCD module. 2. The MTP erase voltage should not be applied when placing and removing the LCD module. 3. The MTP erase voltage should not be applied before VDDIO/VDDEXT/VCI. 4. After Erasing MTP is finished, the capacitors at VGH and VCIX2 must be discharged completely before removing the LCD module. Figure 10-3: MTP Erase circuitry SSD2123 + - VGH Note: GND C = 1uF (built-in on the module) 9V GND MTP Re-Write cycle Table 10-1: MTP Re-write cycle Characteristics Re-write Cycle Power Supply voltage for programming Power Supply voltage for erase Program time Erase time SSD2123 Rev 0.30 P 39/66 Jan 2008 Symbol Min Typ Max Units N VGH VGH Tprog Terase - 14.5 9 0.5 1 5 - Cycle V V s s Solomon Systech Figure 10-4: MTP Erase Flowchart MTP Erase Sequence Turn off and Power down the module Connect a power supply to the module [e.g. VCI = 3.3V, VDDEXT = VDDIO = 3.3V, REGVDD =High]* Toggle reset pin to reset the module Write commands for erase MTP initialization: Register Value R28h 0006h R29h 80C0h R2Dh 7F50h R0Fh 013Fh Wait 200ms for activation Connect VGH with 9V power supply (Figure 10-3) Write command for erasing MTP: Register Value R28h 0008h Wait 1s for the process Write command for disable erasing MTP: Register Value R28h 0000h Power down the module and remove 9V power supply MTP Erase completed SSD2123 Rev 0.30 P 40/66 Jan 2008 Solomon Systech 11 GAMMA ADJUSTMENT FUNCTION The SSD2123 incorporates gamma adjustment function for the 16M-color display. Gamma adjustment is implemented by deciding the 8-grayscale levels with angle adjustment and micro adjustment register. Also, angle adjustment and micro adjustment is fixed for each of the internal positive and negative polarity. Set up by the liquid crystal panel’s specification. RGB Interface Display Data R7 R6 R5 R4 R3 R2 R1 R0 G7 G6 G5 G4 G3 G2 G1 G0 G7 G6 G5 G4 G3 G2 G1 G0 PKP02 PKP01 PKP00 PKP12 PKP11 PKP10 PKP22 PKP21 PKP20 Positive polarity register V0 PKP32 PKP31 PKP30 PKP42 PKP41 PKP40 8-levels PRP12 PRP11 PRP10 8-bits 8-bits 64 levels PKP52 PKP51 PKP50 PRP02 PRP01 PRP00 8-bits Grayscale amplifier VRP03 VRP02 VRP01 VRP00 VRP14 VRP13 VRP12 VRP11 VRP10 256 grayscale Control <R> 256 grayscale Control <G> 256 grayscale Control <B> LCD Driver LCD Driver LCD Driver G B V255 PKN02 PKN01 PKN00 PKN12 PKN11 PKN10 PKN22 PKN21 PKN20 Negative polarity register PKN32 PKN31 PKN30 R PKN42 PKN41 PKN40 PKN52 PKN51 PKN50 PRN02 PRN01 PRN00 LCD PRN12 PRN11 PRN10 VRN03 VRN02 VRN01 VRN00 VRN14 VRN13 VRN12 VRN11 VRN10 SSD2123 Rev 0.30 P 41/66 Jan 2008 Solomon Systech 11.1 Structure of Grayscale Amplifier Below figure indicates the structure of the grayscale amplifier. It determines 8 levels (VIN0-VIN7) by the gradient adjuster and the micro adjustment register. Also, dividing these levels with ladder resistors generates V0 to V255. Gradient adjustment register VLCD255 PRP0 3 PRP1 Amplitude adjustment register Micro adjustment register PKP0 3 3 PKP1 PKP2 PKP3 3 3 3 PKP4 3 PKP5 VRP0 3 4 VRP1 5 VINP0 V0 VINP1 8 to 1 selector V4 : V18 VINP2 8 to 1 selector VINP3 VINP4 8 to 1 selector Grayscale Amplifier : 8 to 1 selector Ladder resistor V32 V56 V80 : V118 V156 : V190 VINP5 8 to 1 selector V224 : V238 8 to 1 selector VINP6 V252 V253 VINP7 * GND SSD2123 Rev 0.30 V255 Individual ladder resistors are used for positive and negative polarity. P 42/66 Jan 2008 Solomon Systech Ladder resistor for negative polarity Ladder resistor for positive polarity VLCD255 5R 4R 0 to 28R VRHP 1R 5R RP1 RP2 RP3 RP4 RP5 RP6 RP7 1R 16R RP23 1R RP24 RP25 RP26 RP27 RP28 RP29 RP30 1R 0 to 28R VRLP 4R 5R 0 to 31R VRP1 8R PKP0[2:0] KVP1 KVP2 KVP3 KVP4 KVP5 8 to 1 KVP6 selector KVP7 KVP8 PRP0[2:0] KVP9 RP8 KVP10 RP9 KVP11 RP10 KVP12 RP11 KVP13 8 to 1 RP12 KVP14 selector RP13 KVP15 RP14 KVP16 RP15 RP31 RP32 RP33 RP34 RP35 RP36 RP37 RP38 VINP1 PKP1[2:0] VINP2 PKP2[2:0] KVP17 KVP18 KVP19 KVP20 KVP21 8 to 1 KVP22 selector KVP23 KVP24 VINP3 PKP3[2:0] KVP25 KVP26 KVP27 KVP28 KVP29 8 to 1 KVP30 selector KVP31 KVP32 VINP4 PKP4[2:0] KVP33 KVP34 KVP35 KVP36 KVP37 8 to 1 KVP38 selector KVP39 KVP40 PRP1[2:0] KVP41 RP39 KVP42 RP40 KVP43 RP41 KVP44 RP42 KVP45 8 to 1 RP43 KVP46 selector RP44 KVP47 RP45 KVP48 RP46 VRN0[3:0] VRN0 KVP0 RP0 RP16 RP17 RP18 RP19 RP20 RP21 RP22 5R VINP0 VRP0[3:0] 0 to 30R VRP0 VINP5 PKP5[2:0] VINP6 VINP7 5R 4R 0 to 28R VRHN 1R 5R RP47 RN1 RN2 RN3 RN4 RN5 RN6 RN7 RN15 1R 16R RN23 1R RN24 RN25 RN26 RN27 RN28 RN29 RN30 5R 1R 0 to 28R VRLN 4R 5R KVN1 KVN2 KVN3 KVN4 KVN5 8 to 1 KVN6 selector KVN7 KVN8 PRN0[2:0] KVN9 RN8 KVN10 RN9 KVN11 RN10 KVN12 RN11 KVN13 8 to 1 RN12 KVN14 selector RN13 KVN15 RN14 KVN16 RN16 RN17 RN18 RN19 RN20 RN21 RN22 0 to 31R VRN1 8R VRP1[4:0] KVN0 RN0 RN31 RN32 RN33 RN34 RN35 RN36 RN37 RN38 VINN0 PKN0[2:0] VINN1 PKN1[2:0] VINN2 PKN2[2:0] KVN17 KVN18 KVN19 KVN20 KVN21 8 to 1 KVN22 selector KVN23 KVN24 VINN3 PKN3[2:0] KVN25 KVN26 KVN27 KVN28 KVN29 8 to 1 KVN30 selector KVN31 KVN32 VINN4 PKN4[2:0] KVN33 KVN34 KVN35 KVN36 KVN37 8 to 1 KVN38 selector KVN39 KVN40 PRN1[2:0] KVN41 RN39 KVN42 RN40 KVN43 RN41 KVN44 RN42 KVN45 8 to 1 RN43 KVN46 selector RN44 KVN47 RN45 KVN48 RN46 VINN5 PKN5[2:0] VINN6 VINN7 VRN1[4:0] RN47 GND SSD2123 Rev 0.30 P 43/66 Jan 2008 Solomon Systech 11.2 Gamma Adjustment Register This block is the register to set up the grayscale voltage adjusting to the gamma specification of the LCD panel. This register can independent set up to positive/negative polarities and there are three types of register groups to adjust gradient, amplitude, and micro-adjustment on number of the grayscale, characteristics of the grayscale voltage. (Using the same setting for Reference-value and R.G.B.) Following graphics indicates the operation of each adjusting register. Grayscale Number 11.2.1 Micro adjustment Grayscale Voltage Amplitude adjustment Grayscale Voltage Grayscale Voltage Gradient adjustment Grayscale Number Grayscale Number Gradient adjusting register The gradient-adjusting resistor is to adjust around middle gradient, specification of the grayscale number and the grayscale voltage without changing the dynamic range. To accomplish the adjustment, it controls the variable resistors in the middle of the ladder resistor by registers (PRP(N)0 / PRP(N)1) for the grayscale voltage generator. Also, there is an independent resistor on the positive/negative polarities in order for corresponding to asymmetry drive. 11.2.2 Amplitude adjusting register The amplitude-adjusting resistor is to adjust amplitude of the grayscale voltage. To accomplish the adjustment, it controls the variable resistors in the boundary of the ladder resistor by registers (VRP(N)0 / VRP(N)1) for the grayscale voltage generator. Also, there is an independent resistor on the positive/negative polarities as well as the gradientadjusting resistor. 11.2.3 Micro adjusting register The micro-adjusting register is to make subtle adjustment of the grayscale voltage level. To accomplish the adjustment, it controls each reference voltage level by the 8 to 1 selector towards the 8-level reference voltage generated from the ladder resistor. Also, there is an independent resistor on the positive/negative polarities as well as other adjusting resistors. SSD2123 Rev 0.30 P 44/66 Jan 2008 Solomon Systech 11.3 Ladder Resistor / 8 to 1 selector This block outputs the reference voltage of the grayscale voltage. There are two ladder resistors including the variable resistor and the 8 to 1 selector selecting voltage generated by the ladder resistor. The gamma registers control the variable resistors and 8 to 1 selector resistors. Variable Resistor There are 3 types of the variable resistors that are for the gradient and amplitude adjustment. The resistance is set by the resistor (PRP(N)0 / PRP(N)1) and (VRP(N)0 / VRP(N)1) as below. PRP(N)[0:1] 000 001 010 011 100 101 110 111 Resistance 0R 4R 8R 12R 16R 20R 24R 28R VRP(N)0 0000 0001 0010 Resistance 0R 2R 4R VRP(N)1 00000 00001 00010 : Step = 2R : 1110 1111 Resistance 0R 1R 2R : Step = 1R : 28R 30R 11110 11111 30R 31R 8 to 1 selecter In the 8 to 1 selector, a reference voltage VIN can be selected from the levels which are generated by the ladder resistors. There are six types of reference voltage (VIN1 to VIN6) and totally 48 divided voltages can be selected in one ladder resistor. Following figure explains the relationship between the micro-adjusting register and the selecting voltage. Registor PKP[2:0] 000 001 010 011 100 101 110 111 SSD2123 VINP1 KVP1 KVP2 KVP3 KVP4 KVP5 KVP6 KVP7 KVP8 Postive polarity Selected voltage VINP2 VINP3 VINP4 KVP9 KVP17 KVP25 KVP10 KVP18 KVP26 KVP11 KVP19 KVP27 KVP12 KVP20 KVP28 KVP13 KVP21 KVP29 KVP14 KVP22 KVP30 KVP15 KVP23 KVP31 KVP16 KVP24 KVP32 Rev 0.30 P 45/66 VINP5 KVP33 KVP34 KVP35 KVP36 KVP37 KVP38 KVP39 KVP40 Jan 2008 VINP6 KVP41 KVP42 KVP43 KVP44 KVP45 KVP46 KVP47 KVP48 Registor PKN[2:0] 000 001 010 011 100 101 110 111 Negative polarity Selected voltage VINN1 VINN2 VINN3 VINN4 KVN1 KVN9 KVN17 KVN25 KVN2 KVN10 KVN18 KVN26 KVN3 KVN11 KVN19 KVN27 KVN4 KVN12 KVN20 KVN28 KVN5 KVN13 KVN21 KVN29 KVN6 KVN14 KVN22 KVN30 KVN7 KVN15 KVN23 KVN31 KVN8 KVN16 KVN24 KVN32 VINN5 KVN33 KVN34 KVN35 KVN36 KVN37 KVN38 KVN39 KVN40 VINN6 KVN41 KVN42 KVN43 KVN44 KVN45 KVN46 KVN47 KVN48 Solomon Systech Grayscale voltage V0 V1 V2 V3 V4 V5 V6 V7 V8 V9 V10 V11 V12 V13 V14 V15 V16 V17 V18 V19 V20 V21 V22 V23 V24 V25 V26 V27 V28 V29 V30 V31 V32 V33 V34 V35 V36 V37 V38 V39 V40 V41 V42 SSD2123 Formula VINP(N)0 (V0-V4)*(30/40)+V4 (V0-V4)*(20/40)+V4 (V0-V4)*(10/40)+V4 VINP(N)1 (V4-V32)*(174/192)+V32 (V4-V32)*(156/192)+V32 (V4-V32)*(138/192)+V32 (V4-V32)*(120/192)+V32 (V4-V32)*(113/192)+V32 (V4-V32)*(106/192)+V32 (V4-V32)*(99/192)+V32 (V4-V32)*(92/192)+V32 (V4-V32)*(85/192)+V32 (V4-V32)*(78/192)+V32 (V4-V32)*(71/192)+V32 (V4-V32)*(64/192)+V32 (V4-V32)*(60/192)+V32 (V4-V32)*(56/192)+V32 (V4-V32)*(52/192)+V32 (V4-V32)*(48/192)+V32 (V4-V32)*(44/192)+V32 (V4-V32)*(40/192)+V32 (V4-V32)*(36/192)+V32 (V4-V32)*(32/192)+V32 (V4-V32)*(28/192)+V32 (V4-V32)*(24/192)+V32 (V4-V32)*(20/192)+V32 (V4-V32)*(16/192)+V32 (V4-V32)*(12/192)+V32 (V4-V32)*(8/192)+V32 (V4-V32)*(4/192)+V32 VINP(N)2 (V32-V80)*(47/48)+V80 (V32-V80)*(46/48)+V80 (V32-V80)*(45/48)+V80 (V32-V80)*(44/48)+V80 (V32-V80)*(43/48)+V80 (V32-V80)*(42/48)+V80 (V32-V80)*(41/48)+V80 (V32-V80)*(40/48)+V80 (V32-V80)*(39/48)+V80 (V32-V80)*(38/48)+V80 Rev 0.30 P 46/66 Grayscale voltage V43 V44 V45 V46 V47 V48 V49 V50 V51 V52 V53 V54 V55 V56 V57 V58 V59 V60 V61 V62 V63 V64 V65 V66 V67 V68 V69 V70 V71 V72 V73 V74 V75 V76 V77 V78 V79 V80 V81 V82 V83 V84 V85 Jan 2008 Formula (V32-V80)*(37/48)+V80 (V32-V80)*(36/48)+V80 (V32-V80)*(35/48)+V80 (V32-V80)*(34/48)+V80 (V32-V80)*(33/48)+V80 (V32-V80)*(32/48)+V80 (V32-V80)*(31/48)+V80 (V32-V80)*(30/48)+V80 (V32-V80)*(29/48)+V80 (V32-V80)*(28/48)+V80 (V32-V80)*(27/48)+V80 (V32-V80)*(26/48)+V80 (V32-V80)*(25/48)+V80 (V32-V80)*(24/48)+V80 (V32-V80)*(23/48)+V80 (V32-V80)*(22/48)+V80 (V32-V80)*(21/48)+V80 (V32-V80)*(20/48)+V80 (V32-V80)*(19/48)+V80 (V32-V80)*(18/48)+V80 (V32-V80)*(17/48)+V80 (V32-V80)*(16/48)+V80 (V32-V80)*(15/48)+V80 (V32-V80)*(14/48)+V80 (V32-V80)*(13/48)+V80 (V32-V80)*(12/48)+V80 (V32-V80)*(11/48)+V80 (V32-V80)*(10/48)+V80 (V32-V80)*(9/48)+V80 (V32-V80)*(8/48)+V80 (V32-V80)*(7/48)+V80 (V32-V80)*(6/48)+V80 (V32-V80)*(5/48)+V80 (V32-V80)*(4/48)+V80 (V32-V80)*(3/48)+V80 (V32-V80)*(2/48)+V80 (V32-V80)*(1/48)+V80 VINP(N)3 (V80-V176)*(95/96)+V176 (V80-V176)*(94/96)+V176 (V80-V176)*(93/96)+V176 (V80-V176)*(92/96)+V176 (V80-V176)*(91/96)+V176 Grayscale voltage V86 V87 V88 V89 V90 V91 V92 V93 V94 V95 V96 V97 V98 V99 V100 V101 V102 V103 V104 V105 V106 V107 V108 V109 V110 V111 V112 V113 V114 V115 V116 V117 V118 V119 V120 V121 V122 V123 V124 V125 V126 V127 V128 Formula (V80-V176)*(90/96)+V176 (V80-V176)*(89/96)+V176 (V80-V176)*(88/96)+V176 (V80-V176)*(87/96)+V176 (V80-V176)*(86/96)+V176 (V80-V176)*(85/96)+V176 (V80-V176)*(84/96)+V176 (V80-V176)*(83/96)+V176 (V80-V176)*(82/96)+V176 (V80-V176)*(81/96)+V176 (V80-V176)*(80/96)+V176 (V80-V176)*(79/96)+V176 (V80-V176)*(78/96)+V176 (V80-V176)*(77/96)+V176 (V80-V176)*(76/96)+V176 (V80-V176)*(75/96)+V176 (V80-V176)*(74/96)+V176 (V80-V176)*(73/96)+V176 (V80-V176)*(72/96)+V176 (V80-V176)*(71/96)+V176 (V80-V176)*(70/96)+V176 (V80-V176)*(69/96)+V176 (V80-V176)*(68/96)+V176 (V80-V176)*(67/96)+V176 (V80-V176)*(66/96)+V176 (V80-V176)*(65/96)+V176 (V80-V176)*(64/96)+V176 (V80-V176)*(63/96)+V176 (V80-V176)*(62/96)+V176 (V80-V176)*(61/96)+V176 (V80-V176)*(60/96)+V176 (V80-V176)*(59/96)+V176 (V80-V176)*(58/96)+V176 (V80-V176)*(57/96)+V176 (V80-V176)*(56/96)+V176 (V80-V176)*(55/96)+V176 (V80-V176)*(54/96)+V176 (V80-V176)*(53/96)+V176 (V80-V176)*(52/96)+V176 (V80-V176)*(51/96)+V176 (V80-V176)*(50/96)+V176 (V80-V176)*(49/96)+V176 (V80-V176)*(48/96)+V176 Solomon Systech Grayscale voltage V129 V130 V131 V132 V133 V134 V135 V136 V137 V138 V139 V140 V141 V142 V143 V144 V145 V146 V147 V148 V149 V150 V151 V152 V153 V154 V155 V156 V157 V158 V159 V160 V161 V162 V163 V164 V165 V166 V167 V168 V169 V170 V171 SSD2123 Formula (V80-V176)*(47/96)+V176 (V80-V176)*(46/96)+V176 (V80-V176)*(45/96)+V176 (V80-V176)*(44/96)+V176 (V80-V176)*(43/96)+V176 (V80-V176)*(42/96)+V176 (V80-V176)*(41/96)+V176 (V80-V176)*(40/96)+V176 (V80-V176)*(39/96)+V176 (V80-V176)*(38/96)+V176 (V80-V176)*(37/96)+V176 (V80-V176)*(36/96)+V176 (V80-V176)*(35/96)+V176 (V80-V176)*(34/96)+V176 (V80-V176)*(33/96)+V176 (V80-V176)*(32/96)+V176 (V80-V176)*(31/96)+V176 (V80-V176)*(30/96)+V176 (V80-V176)*(29/96)+V176 (V80-V176)*(28/96)+V176 (V80-V176)*(27/96)+V176 (V80-V176)*(26/96)+V176 (V80-V176)*(25/96)+V176 (V80-V176)*(24/96)+V176 (V80-V176)*(23/96)+V176 (V80-V176)*(22/96)+V176 (V80-V176)*(21/96)+V176 (V80-V176)*(20/96)+V176 (V80-V176)*(19/96)+V176 (V80-V176)*(18/96)+V176 (V80-V176)*(17/96)+V176 (V80-V176)*(16/96)+V176 (V80-V176)*(15/96)+V176 (V80-V176)*(14/96)+V176 (V80-V176)*(13/96)+V176 (V80-V176)*(12/96)+V176 (V80-V176)*(11/96)+V176 (V80-V176)*(10/96)+V176 (V80-V176)*(9/96)+V176 (V80-V176)*(8/96)+V176 (V80-V176)*(7/96)+V176 (V80-V176)*(6/96)+V176 (V80-V176)*(5/96)+V176 Rev 0.30 P 47/66 Grayscale voltage V172 V173 V174 V175 V176 V177 V178 V179 V180 V181 V182 V183 V184 V185 V186 V187 V188 V189 V190 V191 V192 V193 V194 V195 V196 V197 V198 V199 V200 V201 V202 V203 V204 V205 V206 V207 V208 V209 V210 V211 V212 V213 V214 Jan 2008 Formula (V80-V176)*(4/96)+V176 (V80-V176)*(3/96)+V176 (V80-V176)*(2/96)+V176 (V80-V176)*(1/96)+V176 VINP(N)4 (V176-V224)*(47/48)+V224 (V176-V224)*(46/48)+V224 (V176-V224)*(45/48)+V224 (V176-V224)*(44/48)+V224 (V176-V224)*(43/48)+V224 (V176-V224)*(42/48)+V224 (V176-V224)*(41/48)+V224 (V176-V224)*(40/48)+V224 (V176-V224)*(39/48)+V224 (V176-V224)*(38/48)+V224 (V176-V224)*(37/48)+V224 (V176-V224)*(36/48)+V224 (V176-V224)*(35/48)+V224 (V176-V224)*(34/48)+V224 (V176-V224)*(33/48)+V224 (V176-V224)*(32/48)+V224 (V176-V224)*(31/48)+V224 (V176-V224)*(30/48)+V224 (V176-V224)*(29/48)+V224 (V176-V224)*(28/48)+V224 (V176-V224)*(27/48)+V224 (V176-V224)*(26/48)+V224 (V176-V224)*(25/48)+V224 (V176-V224)*(24/48)+V224 (V176-V224)*(23/48)+V224 (V176-V224)*(22/48)+V224 (V176-V224)*(21/48)+V224 (V176-V224)*(20/48)+V224 (V176-V224)*(19/48)+V224 (V176-V224)*(18/48)+V224 (V176-V224)*(17/48)+V224 (V176-V224)*(16/48)+V224 (V176-V224)*(15/48)+V224 (V176-V224)*(14/48)+V224 (V176-V224)*(13/48)+V224 (V176-V224)*(12/48)+V224 (V176-V224)*(11/48)+V224 (V176-V224)*(10/48)+V224 Grayscale voltage V215 V216 V217 V218 V219 V220 V221 V222 V223 V224 V225 V226 V227 V228 V229 V230 V231 V232 V233 V234 V235 V236 V237 V238 V239 V240 V241 V242 V243 V244 V245 V246 V247 V248 V249 V250 V251 V252 V253 V254 V255 Formula (V176-V224)*(9/48)+V224 (V176-V224)*(8/48)+V224 (V176-V224)*(7/48)+V224 (V176-V224)*(6/48)+V224 (V176-V224)*(5/48)+V224 (V176-V224)*(4/48)+V224 (V176-V224)*(3/48)+V224 (V176-V224)*(2/48)+V224 (V176-V224)*(1/48)+V224 VINP(N)5 (V224-V252)*(188/192)+V252 (V224-V252)*(184/192)+V252 (V224-V252)*(180/192)+V252 (V224-V252)*(176/192)+V252 (V224-V252)*(172/192)+V252 (V224-V252)*(168/192)+V252 (V224-V252)*(164/192)+V252 (V224-V252)*(160/192)+V252 (V224-V252)*(156/192)+V252 (V224-V252)*(152/192)+V252 (V224-V252)*(148/192)+V252 (V224-V252)*(144/192)+V252 (V224-V252)*(140/192)+V252 (V224-V252)*(136/192)+V252 (V224-V252)*(132/192)+V252 (V224-V252)*(128/192)+V252 (V224-V252)*(121/192)+V252 (V224-V252)*(114/192)+V252 (V224-V252)*(107/192)+V252 (V224-V252)*(100/192)+V252 (V224-V252)*(93/192)+V252 (V224-V252)*(86/192)+V252 (V224-V252)*(79/192)+V252 (V224-V252)*(72/192)+V252 (V224-V252)*(54/192)+V252 (V224-V252)*(36/192)+V252 (V224-V252)*(18/192)+V252 VINP(N)6 (V252-V255)*(20/30)+V255 (V252-V255)*(10/30)+V255 VINP(N)7 Solomon Systech Reference voltage of positive polarity: Micr0-adjusting rgister -KVP0 VLCD255 - ΔV x VRP0 / SUMRP PKP0[2:0] = “000” KVP1 VLCD255 - ΔV x (VRP0 + 5R) / SUMRP PKP0[2:0] = “001” KVP2 VLCD255 - ΔV x (VRP0 + 9R) / SUMRP PKP0[2:0] = “010” KVP3 VLCD255 - ΔV x (VRP0 + 13R) / SUMRP PKP0[2:0] = “011” KVP4 VLCD255 - ΔV x (VRP0 + 17R) / SUMRP PKP0[2:0] = “100” KVP5 VLCD255 - ΔV x (VRP0 + 21R) / SUMRP PKP0[2:0] = “101” VLCD255 - ΔV x (VRP0 + 25R) / SUMRP KVP6 PKP0[2:0] = “110” KVP7 VLCD255 - ΔV x (VRP0 + 29R) / SUMRP PKP0[2:0] = “111” KVP8 VLCD255 - ΔV x (VRP0 + 33R) / SUMRP PKP1[2:0] = “000” KVP9 VLCD255 - ΔV x (VRP0 + 33R + VRHP) / SUMRP PKP1[2:0] = “001” KVP10 VLCD255 - ΔV x (VRP0 + 34R + VRHP) / SUMRP PKP1[2:0] = “010” KVP11 VLCD255 - ΔV x (VRP0 + 35R + VRHP) / SUMRP PKP1[2:0] = “011” KVP12 VLCD255 - ΔV x (VRP0 + 36R + VRHP) / SUMRP PKP1[2:0] = “100” KVP13 VLCD255 - ΔV x (VRP0 + 37R + VRHP) / SUMRP PKP1[2:0] = “101” KVP14 VLCD255 - ΔV x (VRP0 + 38R + VRHP) / SUMRP PKP1[2:0] = “110” KVP15 VLCD255 - ΔV x (VRP0 + 39R + VRHP) / SUMRP PKP1[2:0] = “111” KVP16 VLCD255 - ΔV x (VRP0 + 40R + VRHP) / SUMRP PKP2[2:0] = “000” KVP17 VLCD255 - ΔV x (VRP0 + 45R + VRHP) / SUMRP PKP2[2:0] = “001” KVP18 VLCD255 - ΔV x (VRP0 + 46R + VRHP) / SUMRP PKP2[2:0] = “010” KVP19 VLCD255 - ΔV x (VRP0 + 47R + VRHP) / SUMRP PKP2[2:0] = “011” KVP20 VLCD255 - ΔV x (VRP0 + 48R + VRHP) / SUMRP PKP2[2:0] = “100” KVP21 VLCD255 - ΔV x (VRP0 + 49R + VRHP) / SUMRP PKP2[2:0] = “101” KVP22 VLCD255 - ΔV x (VRP0 + 50R + VRHP) / SUMRP PKP2[2:0] = “110” KVP23 VLCD255 - ΔV x (VRP0 + 51R + VRHP) / SUMRP PKP2[2:0] = “111” KVP24 VLCD255 - ΔV x (VRP0 + 52R + VRHP) / SUMRP PKP3[2:0] = “000” KVP25 VLCD255 - ΔV x (VRP0 + 68R + VRHP) / SUMRP PKP3[2:0] = “001” KVP26 VLCD255 - ΔV x (VRP0 + 69R + VRHP) / SUMRP PKP3[2:0] = “010” KVP27 VLCD255 - ΔV x (VRP0 + 70R + VRHP) / SUMRP PKP3[2:0] = “011” KVP28 VLCD255 - ΔV x (VRP0 + 71R + VRHP) / SUMRP PKP3[2:0] = “100” KVP29 VLCD255 - ΔV x (VRP0 + 72R + VRHP) / SUMRP PKP3[2:0] = “101” KVP30 VLCD255 - ΔV x (VRP0 + 73R + VRHP) / SUMRP PKP3[2:0] = “110” KVP31 VLCD255 - ΔV x (VRP0 + 74R + VRHP) / SUMRP PKP3[2:0] = “111” KVP32 VLCD255 - ΔV x (VRP0 + 75R + VRHP) / SUMRP PKP4[2:0] = “000” KVP33 VLCD255 - ΔV x (VRP0 + 80R + VRHP) / SUMRP PKP4[2:0] = “001” KVP34 VLCD255 - ΔV x (VRP0 + 81R + VRHP) / SUMRP PKP4[2:0] = “010” KVP35 VLCD255 - ΔV x (VRP0 + 82R + VRHP) / SUMRP PKP4[2:0] = “011” KVP36 VLCD255 - ΔV x (VRP0 + 83R + VRHP) / SUMRP PKP4[2:0] = “100” KVP37 VLCD255 - ΔV x (VRP0 + 84R + VRHP) / SUMRP PKP4[2:0] = “101” KVP38 VLCD255 - ΔV x (VRP0 + 85R + VRHP) / SUMRP PKP4[2:0] = “110” KVP39 VLCD255 - ΔV x (VRP0 + 86R + VRHP) / SUMRP PKP4[2:0] = “111” KVP40 VLCD255 - ΔV x (VRP0 + 87R + VRHP) / SUMRP PKP5[2:0] = “000” KVP41 VLCD255 - ΔV x (VRP0 + 87R + VRHP + VRLP) / SUMRP PKP5[2:0] = “001” KVP42 VLCD255 - ΔV x (VRP0 + 91R + VRHP + VRLP) / SUMRP PKP5[2:0] = “010” KVP43 VLCD255 - ΔV x (VRP0 + 91R + VRHP + VRLP) / SUMRP PKP5[2:0] = “011” KVP44 VLCD255 - ΔV x (VRP0 + 99R + VRHP + VRLP) / SUMRP PKP5[2:0] = “100” KVP45 VLCD255 - ΔV x (VRP0 + 103R + VRHP + VRLP) / SUMRP PKP5[2:0] = “101” KVP46 VLCD255 - ΔV x (VRP0 + 107R + VRHP + VRLP) / SUMRP PKP5[2:0] = “110” KVP47 VLCD255 - ΔV x (VRP0 + 111R + VRHP + VRLP) / SUMRP PKP5[2:0] = “111” KVP48 VLCD255 - ΔV x (VRP0 + 115R + VRHP + VRLP) / SUMRP -KVP49 VLCD255 - ΔV x (VRP0 + 120R + VRHP + VRLP) / SUMRP SUMRP: Total of the positive polarity ladder resistance = 128R + VRHP + VRLP + VRP0 + VRP1 ΔV: Voltage difference between VLCD255 and of GND. Reference SSD2123 Formula Rev 0.30 P 48/66 Jan 2008 Reference voltage VINP0 VINP1 VINP2 VINP3 VINP4 VINP5 VINP6 VINP7 Solomon Systech Reference voltage of negative polarity: Reference KVN0 KVN1 KVN2 KVN3 KVN4 KVN5 KVN6 KVN7 KVN8 KVN9 KVN10 KVN11 KVN12 KVN13 KVN14 KVN15 KVN16 KVN17 KVN18 KVN19 KVN20 KVN21 KVN22 KVN23 KVN24 KVN25 KVN26 KVN27 KVN28 KVN29 KVN30 KVN31 KVN32 KVN33 KVN34 KVN35 KVN36 KVN37 KVN38 KVN39 KVN40 KVN41 KVN42 KVN43 KVN44 KVN45 KVN46 KVN47 KVN48 KVN49 Formula VLCD255 - ΔV x VRN0 / SUMRN VLCD255 - ΔV x (VRN0 + 5R) / SUMRN VLCD255 - ΔV x (VRN0 + 9R) / SUMRN VLCD255 - ΔV x (VRN0 + 13R) / SUMRN VLCD255 - ΔV x (VRN0 + 17R) / SUMRN VLCD255 - ΔV x (VRN0 + 21R) / SUMRN VLCD255 - ΔV x (VRN0 + 25R) / SUMRN VLCD255 - ΔV x (VRN0 + 29R) / SUMRN VLCD255 - ΔV x (VRN0 + 33R) / SUMRN VLCD255 - ΔV x (VRN0 + 33R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 34R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 35R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 36R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 37R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 38R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 39R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 40R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 45R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 46R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 47R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 48R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 49R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 50R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 51R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 52R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 68R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 69R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 70R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 71R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 72R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 73R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 74R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 75R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 80R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 81R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 82R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 83R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 84R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 85R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 86R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 87R + VRHN) / SUMRN VLCD255 - ΔV x (VRN0 + 87R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 91R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 95R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 99R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 103R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 107R + VRHN + VRLN) / SUMRN VLCD255-ΔV x (VRN0 + 111R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 115R + VRHN + VRLN) / SUMRN VLCD255 - ΔV x (VRN0 + 120R + VRHN + VRLN) / SUMRN Micr0-adjusting rgister -PKN0[2:0] = “000” PKN0[2:0] = “001” PKN0[2:0] = “010” PKN0[2:0] = “011” PKN0[2:0] = “100” PKN0[2:0] = “101” PKN0[2:0] = “110” PKN0[2:0] = “111” PKN1[2:0] = “000” PKN1[2:0] = “001” PKN1[2:0] = “010” PKN1[2:0] = “011” PKN1[2:0] = “100” PKN1[2:0] = “101” PKN1[2:0] = “110” PKN1[2:0] = “111” PKN2[2:0] = “000” PKN2[2:0] = “001” PKN2[2:0] = “010” PKN2[2:0] = “011” PKN2[2:0] = “100” PKN2[2:0] = “101” PKN2[2:0] = “110” PKN2[2:0] = “111” PKN3[2:0] = “000” PKN3[2:0] = “001” PKN3[2:0] = “010” PKN3[2:0] = “011” PKN3[2:0] = “100” PKN3[2:0] = “101” PKN3[2:0] = “110” PKN3[2:0] = “111” PKN4[2:0] = “000” PKN4[2:0] = “001” PKN4[2:0] = “010” PKN4[2:0] = “011” PKN4[2:0] = “100” PKN4[2:0] = “101” PKN4[2:0] = “110” PKN4[2:0] = “111” PKN5[2:0] = “000” PKN5[2:0] = “001” PKN5[2:0] = “010” PKN5[2:0] = “011” PKN5[2:0] = “100” PKN5[2:0] = “101” PKN5[2:0] = “110” PKN5[2:0] = “111” -- Reference voltage VINN0 VINN1 VINN2 VINN3 VINN4 VINN5 VINN6 VINN7 SUMRN: Total of the negative polarity ladder resistance = 128R + VRHN + VRLN + VRN0 + VRN1 ΔV: Voltage difference between VLCD255 and of GND. SSD2123 Rev 0.30 P 49/66 Jan 2008 Solomon Systech 12 Block Function Description Serial Interface Serial Interface – 4-wires (8 bits) The clock synchronized serial peripheral interface (SPI) using the chip select line (CSB), serial transfer clock line (SCK), serial input data (SDI). The serial data transfer starts at the falling edge of CSB input and ends at the rising edge of CSB.SDC determinate the data of SDI which is register or data. Transfer starts Transfer ends Transfer starts Transfer ends Transfer starts Transfer ends CSB SDC 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 1 2 3 4 5 6 7 8 SCK LSB MSB DB DB 6 7 SDI DB DB DB DB 4 2 5 3 LSB MSB Register LSB MSB DB DB DB DB DB DB DB DB 8 9 15 14 13 12 11 10 DB DB 0 1 DB DB DB DB DB DB DB DB 0 6 5 4 3 2 1 7 Data Data Example of 4-wires (8 bits) Frame 1 (Command 10h) Transfer starts Frame 2 (Data 5Ah) Transfer ends Transfer starts CSB CSB SDC SDC SCK 1 2 3 4 5 6 7 SCK 8 1 Transfer ends 2 3 4 5 6 7 8 SDI SDI Frame 3 (Data 78h) Transfer starts Transfer ends CSB SDC SCK 1 2 3 4 5 6 7 8 SDI SSD2123 Rev 0.30 P 50/66 Jan 2008 Solomon Systech Serial Interface – 3-wires (9 bits) The clock synchronized serial peripheral interface (SPI) using the chip select line (CSB), serial transfer clock line (SCK), serial input data (SDI). The serial data transfer starts at the falling edge of CSB input and ends at the rising edge of CSB. DC bit determinate the data of SDI which is register or data. Transfer starts Transfer ends Transfer starts Transfer ends Transfer starts Transfer ends CSB 1 2 3 SCK 4 5 6 7 8 1 LSB MSB 2 3 4 5 D Register 6 7 8 9 1 LSB MSB DB DB DB DB DB DB DB DB 0 6 4 2 5 3 1 7 C SDI 9 2 3 4 5 6 D 8 9 LSB MSB DB DB DB DB DB DB DB DB 8 9 15 14 13 12 11 10 7 DB 7 DB DB DB DB DB DB DB 0 6 5 4 3 2 1 Data Data Example of 3-wires (9 bits) Frame 1 (Command 10h) Transfer starts Frame 2 (Data 5Ah) Transfer ends CSB Transfer starts Transfer ends CSB 1 2 3 4 5 6 7 8 1 9 SCK SCK SDI SDI 2 3 4 5 6 7 8 9 Frame 3 (Data 78h) Transfer starts Transfer ends CSB 1 2 3 4 5 6 7 8 9 SCK SDI SSD2123 Rev 0.30 P 51/66 Jan 2008 Solomon Systech Serial Interface – 3-wires (24 bits) The clock synchronized serial peripheral interface (SPI) using the chip select line (CSB), serial transfer clock line (SCK), serial input data (SDI), and serial output data (SDO). The serial data transfer starts at the falling edge of CSB input and ends at the rising edge of CSB. DC bit determinate the data of SDI which is register or data. RW bit determinate the read / write operation. Write Transfer starts Transfer ends CSB SCK SDI 1 2 3 4 5 6 7 8 “0” “1” “1” “1” “0” ID ID DC RW 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 DB 14 DB 13 DB 12 DB 11 DB 10 DB 9 DB 8 DB 7 DB 6 DB 5 DB 4 DB 3 DB 2 DB 1 LSB MSB DB 15 24 DB 0 DC RW Device ID code Index register setting / Instruction, Start byte Read st 1 step read - Index register Transfer starts CSB SCK Transfer 1 2 3 4 5 6 7 8 “0” “1” “1” “1” “0” ID ID C R 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 DB 14 DB 13 DB 12 DB 11 DB 10 DB 9 DB 8 DB 7 DB 6 DB 5 DB 4 DB 3 DB 2 DB 1 LSB MSB SDI DB 15 24 DB 0 DC RW Device ID code Index register setting / Instruction, Start byte SDO Transfer starts Transfer CSB 1 2 3 4 5 6 7 8 “0” “1” “1” “1” “0” ID ID D R 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 DB 14 DB 13 DB 12 DB 11 DB 10 DB 9 DB 8 DB 7 DB 6 DB 5 DB 4 DB 3 DB 2 DB 1 DB 0 DB 3 DB 2 DB 1 DB 0 SCK 2nd step read - Data at SDO LSB MSB SDI Device ID code DB 15 DC RW Index register setting / Instruction, Start byte DB 15 DB 14 DB 13 DB 12 DB 11 DB 10 DB 9 DB 8 DB 7 DB 6 DB 5 DB 4 SDO Status read SSD2123 Rev 0.30 P 52/66 Jan 2008 Solomon Systech Data Control The display data and frame position information from the controller is synchronized with the Gate Drive circuit and shift registered for the Source Driver circuit. Booster and Regulator Circuit These two functional blocks generate the voltage of VGH, VGL, VCOM and VLCD255 which are necessary for operating a TFT LCD. Shift Register The shift registers control the direction of line scanning of source and gate. Data Latches This block is a series of latches carrying the display signal information. These latches hold the data, which will be fed to the Source Driver to output the required voltage level. Reset Circuit This block is integrated into the Interface Logic which includes Power On Reset circuitry and the hardware reset pin, RES . Both of these having the same reset function. Once the RES pin receives a negative reset pulse, all internal circuitry will start to initialize. The minimum pulse width for completing the reset sequence is 10us. The status of the chip after reset is given in Command Table: SSD2123 Rev 0.30 P 53/66 Jan 2008 Solomon Systech 13 DC CHARACTERISTICS DC Characteristics (Unless otherwise specified, Voltage Referenced to VSS, TA = -40 to 85oC) Symbol Parameter VDDIO Power supply pin of IO pins Isleep1 Isleep2 Booster Reference Supply Voltage Range (3) Sleep mode current (VCI pin) Sleep mode current (VDDIO) Idp Operating mode current VCIM Negative VCI Output Voltage VCI AVDD VGH VGL VCOMH VCOML VCOMA VLCD255 ΔVLCD255 VOH1 VOL1 VIH1 VIL1 IOH IOL IOZ IIL/IIH CIN RSON RGON RCON TC Note1: Note2: Note3: Test Condition Recommend Operating Voltage Possible Operating Voltage Recommend Operating Voltage Possible Operating Voltage VDDEXT=VDDIO=1.875V, VCI=2.775V 1 AVDD x 2 primary booster efficiency Gate driver High Output Voltage Booster efficiency2 Gate driver Low Output Voltage VCOM High Output Voltage VCOM Low Output Voltage VCOMA VCOMH - VCOML VLCD255 Output Voltage3 Max. Source Voltage Variation Logic High Output Voltage Logic Low Output Voltage Logic High Input voltage Logic Low Input voltage Logic High Output Current Source Logic Low Output Current Drain Logic Output Tri-state Current Drain Source Logic Input Current Logic Pins Input Capacitance Source drivers output resistance Gate drivers output resistance VCOM output resistance Temperature Coefficient 100pF loading at Source output VDDEXT=VDDIO=1.875V, VCI=2.775V No panel loading No panel loading, ITO for CYP, CYN, AVDD, VCI and VCHS = 10 Ohm No panel loading; 4x booster; ITO for CYP, CYN, AVDD, VCI and VCHS = 10 Ohm No panel loading; 5x booster; ITO for CYP, CYN, AVDD, VCI and VCHS = 10 Ohm No panel loading; 6x booster; ITO for CYP, CYN, AVDD, VCI and VCHS = 10 Ohm Iout=-100A Iout=100A Vout = VDDIO-0.4V Vout = 0.4V Min Typ 1.6 - Max Unit 3.6 V 2.5 or VDDIO - 3.6 V - TBA TBA TBA TBA uA uA - TBA TBA mA -VCI - 91 - 6.1 V % V TBA 89.5 - % TBA 88.5 - % TBA 80 - % - 15.0 VCIM+0.5 -2 0.9 * VDDIO 0 0.8 * VDDIO 0 TBA - - - - 6.0 6.0 6.0 6.0 6.0 2 VDDIO 0.1 * VDDIO VDDIO 0.2 * VDDIO TBA V V V V V V % V V V V μA μA TBA - TBA μA TBA - 5 1 500 200 -0.01 TBA 7.5 - μA pF kΩ Ω Ω % AVDDX2 efficiency = AVDD /(2 x VCI) x 100% VGH efficiency = VGH/(VCI x n) x 100% (where n = booster factor) AVDD – VLCD255 ≥ 0.1V SSD2123 Rev 0.30 P 54/66 Jan 2008 Solomon Systech 14 AC CHARACTERISTICS 14.1 Display signal output timing 1 Frame Row 0 Row 1 Row 271 Row 0 Row 1 VSYNC HSYNC Polarity + + + - - - - - - + + + GR0 GG0 GB0 GR1 GG1 GB1 . . . GRn GGn GBn Sm (All black pattern) tvbp tvfp tHSYN tSm tVSYNC Figure 14-1: Gate and source output timing (Line inversion) Symbol Parameter tVSYNC tHSYNC tSm tvbp tvfp 1 / Frame Frequency 1 / Line Frequency 1 / Source Frequency Delay time between each field Delay time between each field SSD2123 Rev 0.30 P 55/66 Jan 2008 Min Typ Max Unit - 16.7 61.3 20.4 TBD TBD - ms us us us us Solomon Systech Figure 14-2- Example of color filter arrangement GR0 GG0 GB0 GR1 GG1 GB1 GR2 GG2 GB2 GR3 GG3 GB3 GR268 GG268 GB268 GR269 GG269 GB269 GR270 GG270 GB270 SSD2123 Rev 0.30 P 56/66 Jan 2008 S479 S478 S477 S476 S475 S474 S473 S472 S471 S470 S469 S468 S467 S12 S11 S10 S9 S8 S7 S6 S5 S4 S3 S2 S1 S0 GR271 GG271 GB271 Solomon Systech 14.2 SPI Timing AC Characteristics (Unless otherwise specified, Voltage Referenced to VSS, VDDIO = 1.875V, TA = -40 to 85oC) Serial Peripheral Interface (SPI) tvsys VSYNC tvsyh thsys thsyh HSYNC thv tDOTCLK DOTCLK tCKL tds tr tCKH tdh Pixel Data tr / tf Figure 14-3- Pixel Clock Timing Characteristics DOTCLK Frequency DOTCLK Period Vertical Sync Setup Time Vertical Sync Hold Time Horizontal Sync Setup Time Horizontal Sync Hold Time Phase difference of Sync Signal Falling Edge DOTCLK Low Period DOTCLK High Period Data Setup Time Data hold Time Reset pulse width Rise / Fall time Note: SSD2123 Symbol fDOTCLK tDOTCLK tvsys tvsyh thsys thsyh Min - thv TBD Max TBD - - Units MHz nSec nSec nSec nSec nSec - TBD tDOTCLK TBD TBD TBD TBD TBD TBD TBD External clock source must be provided to DOTCLK pin of SSD2123Z. The driver will not operate if absent of the clocking signal. Rev 0.30 P 57/66 tCKL tCKH tds tdh tRES tr / tf TBD TBD TBD TBD TBD Typ TBD TBD Jan 2008 nSec nSec nSec nSec uSec nSec Solomon Systech CM HSYNC VSYNC Color Mode 16.7M color mode 8 color mode 16.7M color mode Figure 14-4 Color Mode Conversion Timing Note: SSD2123 The color mode conversion starts at the first falling edge of VSYNC after stage change of CM. Rev 0.30 P 58/66 Jan 2008 Solomon Systech VDDIO VDDEXT VCI RES SHUT >1ns 10 us >1us DOTCLK >1 CLK VGH < 10 frames < 10 frames < 10 frames VGH Output ~Vci Figure 14-5 VGH Output against SHUT & RESB Note1: The minimum cycle time of SHUT is 10 + 2 frames. Note2: DOTCLK must be provided for boosting of VGH. The above timing diagram assumed voltages and DOTCLK are continuous supplied after power on. Note3: VGH will be forced to VCI at the low stage of RES . Note4: The minimum pulse width of RESET is 10us. SSD2123 Rev 0.30 P 59/66 Jan 2008 Solomon Systech VCI VDDIO VDDEXT >0ms RESB >1ns SHUT tp-shut DOTCLK tclkHSYNC 1st 10th VSYNC tshut- Display High Voltage tshut-on Display ON Figure 14-6 - Power Up Sequence Characteristics VDDEXT / VDDIO on to falling edge of SHUT DOTCLK Falling edge of SHUT to LCD power on Falling edge of SHUT to display start -- 1 line: 336 clk -- 1 frame: 244 line -- DOTCLK = 5.0MHz SSD2123 Symbol tp-shut tclk-shut tshut-lcd tshut-on Min Max - - Typ - TBD TBD Units μsec clk msec frame - TBD - msec TBD TBD Note1: It is necessary to input DOTCLK before the falling edge of SHUT. Note2: Display starts at 10th falling edge of VSTNC after the falling edge of SHUT. Rev 0.30 P 60/66 Jan 2008 Solomon Systech VDD VDDIO toff>1us VCI >1ns RES SHUT DOTCLK HSYNC 1st 2nd VSYNC tshut-offt Display High Voltage Display ON OFF Figure 14-7 - Power Down Sequence Characteristics Rising edge of SHUT to display off -- 1 line: 336 clk -- 1 frame: 244 line -- DOTCLK = 5.0 MHz Input-signal-off to VDDEXT / VDDIO off SSD2123 Symbol Min Typ Max Units TBD - - frame TBD - - msec TBD - - μsec tshut-off toff-vdd Note1: DOTCLK must be maintained at lease 2 frames after the rising edge of SHUT. Note2: Display become off at the 2nd falling edge of VSTNC after the falling edge of SHUT. Note3: If RESET signal is necessary for power down, provide it after the 2-frames-cycle of the SHUT period. Rev 0.30 P 61/66 Jan 2008 Solomon Systech First Transmission (Register) CS tcss 1 2 3 4 5 6 7 8 9 10 11 12 tcsh 13 14 15 16 17 18 19 20 21 22 23 24 “0” “0” “0” “0” “0” “0” “1” “0” “1” “0” “0” “0” SCL tsl SDI “0” “1” “1” “1” “0” ID DC tsh RW “0” “0” “0” “0” Second Transmission (Data) CS 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 “0” “1” “1” “1” “0” ID DC RW “0” “0” “0” “1” “0” “0” “1” “0” “0” “1” “1” “0” “0” “1” “0” “0” tcsd SCL SDI tds tdh Figure 14-8 - SPI Interface Timing Diagram & Transaction Example Characteristics Serial Clock Frequency Serial Clock Cycle Time Clock Low Width Clock High Width Chip Select Setup Time Chip Select Hold Time Chip Select High Delay Time Data Setup Time Data Hold Time Note1: SSD2123 Symbol fclk tclk tsl tsh tcss tcsh tcsd tds tdh Min TBD TBD TBD TBD TBD TBD TBD TBD Typ - Max TBD - Units MHz nsec nsec nsec nsec nsec nsec msec nsec SPID pin connected to VSS. Rev 0.30 P 62/66 Jan 2008 Solomon Systech 14.3 8-bit Serial Interface HV SYNC Mode YSYNC HSYNC tDEN DEN Mode DEN RR[7:0] Line 1 Line 2 Line 3 Line 4 Line 5 Line 6 Line 7 Line 8 Line 9 Line 10 Line 11 Line 12 Line 13 Line 14 Line 15 Line 16 Line n tV HV SYNC Mode HSYNC DOTCLK tHBP DEN Mode DEN Without Dummy RR[7:0] R0 Invalid Data G0 B0 R1 G1 B1 R2 G2 B2 R3 G3 B3 R4 G4 B4 R5 G5 B5 R6 G6 B6 Figure 14-9 – 8-bit Serial Interface Timing Diagram & Transaction Example Characteristics Serial Clock Frequency One Line Period Active Data Period Horizontal Horizontal Back Porch Horizontal Front Porch One Field Period Active Line period Vertical Vertical Back Porch Vertical Front Porch SSD2123 Rev 0.30 P 63/66 Jan 2008 Symbol 1/tDOTCLK tH tdata tHBP tHFP tV tAL tVBP tVFP HV SYNC Mode Without Dummy 25.62 1536 1440 48 48 278 272 4 2 Units MHz tDOTCLK tDOTCLK tDOTCLK tDOTCLK tH tH tH tH Solomon Systech R7 14.4 24-bit RGB Interface HV SYNC Mode YSYNC HSYNC tDEN DEN Mode DEN RR[7:0] Line 1 Line 2 Line 3 Line 4 Line 5 Line 6 Line 7 Line 8 Line 9 Line 10 Line 11 Line 12 Line 13 Line 14 Line 15 Line 16 Line n GG[7:0] Line 1 Line 2 Line 3 Line 4 Line 5 Line 6 Line 7 Line 8 Line 9 Line 10 Line 11 Line 12 Line 13 Line 14 Line 15 Line 16 Line n BB[7:0] Line 1 Line 2 Line 3 Line 4 Line 5 Line 6 Line 7 Line 8 Line 9 Line 10 Line 11 Line 12 Line 13 Line 14 Line 15 Line n tV HV SYNC Mode HSYNC DOTCLK tHBP DEN Mode DEN RR[7:0] Invalid Data R1 R2 R3 R4 R5 R6 R7 R8 R9 R10 R11 R12 R13 R14 R15 R16 R17 R18 GG[7:0] Invalid Data G1 G2 G3 G4 G5 G6 G7 G8 G9 G10 G11 G12 G13 G14 G15 G16 G17 G18 BB[7:0] Invalid Data B1 B2 B3 B4 B5 B6 B7 B8 B9 B10 B11 B12 B13 B14 B15 B16 B17 B18 R19 B19 R20 R21 R22 G20 G21 G22 B20 B21 B22 Figure 14-10 – 24-bit Serial Interface Timing Diagram & Transaction Example Characteristics Serial Clock Frequency One Line Period Active Data Period Horizontal Horizontal Back Porch Horizontal Front Porch One Field Period Active Line period Vertical Vertical Back Porch Vertical Front Porch SSD2123 Rev 0.30 P 64/66 Jan 2008 Symbol 1/tDOTCLK tH tdata tHBP tHFP tV tAL tVBP tVFP HV SYNC Mode 8.54 Units MHz 512 480 16 16 278 272 4 2 tDOTCLK tDOTCLK tDOTCLK tDOTCLK tH tH tH tH Solomon Systech 15 SSD2123Z OUTPUT VOLTAGE RELATIONSHIP Figure 15-1- LCD Driving Voltage Relationship VGH X3 AVDD VLCD (AVDD – 0.1V max) VCOMH VCI VCOM Amplitude VSS VCOML VCIM VGL Note: SSD2123 The above voltages level assumed 100% efficiency of the internal booster. There has no voltage drop due to resistance from ITO trace of the panel. Rev 0.30 P 65/66 Jan 2008 Solomon Systech Solomon Systech reserves the right to make changes without notice to any products herein. Solomon Systech makes no warranty, representation or guarantee regarding the suitability of its products for any particular purpose, nor does Solomon Systech assume any liability arising out of the application or use of any product or circuit, and specifically disclaims any, and all, liability, including without limitation consequential or incidental damages. “Typical” parameters can and do vary in different applications. All operating parameters, including “Typical” must be validated for each customer application by the customer’s technical experts. Solomon Systech does not convey any license under its patent rights nor the rights of others. Solomon Systech products are not designed, intended, or authorized for use as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any other application in which the failure of the Solomon Systech product could create a situation where personal injury or death may occur. Should Buyer purchase or use Solomon Systech products for any such unintended or unauthorized application, Buyer shall indemnify and hold Solomon Systech and its offices, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such unintended or unauthorized use, even if such claim alleges that Solomon Systech was negligent regarding the design or manufacture of the part. All Solomon Systech Products complied with six (6) hazardous substances limitation requirement per European Union (EU) “Restriction of Hazardous Substance (RoHS) Directive (2002/95/EC)” and China standard “电子信息产品污染控制标识要求 (SJ/T11364-2006)” with control Marking Symbol . Hazardous Substances test report is available upon requested. http://www.solomon-systech.com SSD2123 Rev 0.30 P 66/66 Jan 2008 Solomon Systech