Genesis Microchip Publication PRELIMINARY DATA SHEET gm5110/gm5110-H gm5120/gm5120-H XGA/SXGA LCD Controller *** Genesis Microchip Confidential *** NOTE: Sections in this data sheet that mention HDCP apply only to the HDCP-enabled chip versions (gm5110-H and gm5120-H). All other sections apply to all chip versions (gm5110, gm5110-H, gm5120, and gm5120-H). Publication number: C5110-DAT-01C Publication date: June 2002 Genesis Microchip Inc. 2150 Gold Street, Alviso, P.O. Box 2150, CA USA 95002 Tel: (408) 262-6599 Fax: (408) 262-6365 165 Commerce Valley Dr. West, Thornhill, ON Canada L3T 7V8 Tel: (905) 889-5400 Fax: (905) 889-5422 1096, 12thA Main, Hal II Stage, Indira Nagar, Bangalore-560 008, India, Tel: (91)-80-526-3878, Fax: (91)-80-529-6245 4F, No. 24, Ln 123, Sec 6, Min-Chuan E. Rd., Taipei, Taiwan, ROC Tel: 886-2-2791-0118 Fax: 886-2-2791-0196 143-37 Hyundai Tower, #902, Samsung-dong, Kangnam-gu, Seoul, Korea 135-090 Tel 82-2-553-5693 Fax 82-2-552-4942 Rm2614-2618 Shenzhen Office Tower, 6007 Shennan Blvd, 518040, Shenzhen, Guandong, P.R.C., Tel (0755)386-0101, Fax (0755)386-7874 2-9-5 Higashigotanda, Shinagawa-ku, Tokyo, 141-0022, Japan, Tel 81-3-5798-2758, Fax 81-3-5798-2759 www.genesis-microchip.com / [email protected] *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Revision History Document C5110-DAT-01A C5110-DAT-01B Description • Initial release • Added note on Front Cover regarding HDCP enabled versions. • Added section 4.12 - Energy Spectrum Management (ESM). • In section 4.15 clarified that ROM_ADDR[15:0] have internal 60KΩ pull-down resistor. • Changes to Table 21– DC Characteristics: – Renamed parameters θJA_XGA, θJA_SXGA, θJC_XGA and θJC_SXGA to θJA_5110, θJA_5120, θJC_5110 and θJC_5120 and revised their values. – Added note (4) regarding the maximum case temperature. • Changes to Table 22– Maximum Speed of Operation: – Renamed parameters P5110 and P5120 and revised their values. – Renamed parameters I5110, I5110_2.5_VDD, etc. – Added note (6). • Removed the clock speed column from section 6 - Ordering Information and added the ordering information for gm5110-H and gm5120-H. Date Aug 2001 Oct 2001 D5110-DAT-01C • June 2002 Pins 143 ~ 146: changed xxx_SDDS or xxxx_SDDS to xxx_DDDS or xxxx_DDDS respectively • Pins 138 ~ 141: changed xxx_DDDS or xxxx_DDDS to xxx_SDDS or xxxx_SDDS respectively • Pins 147 ~ 148: changed xxx_DPLL to xxx_RPLL Related documents Chip documents C5110-PBR-01 C5120-PBR-01 C5115-APB-01 C5115-APB-02 C5115-TOP-01 C5115-DSL-01 C5115-DSR-02 Preliminary Product Brief gm5110 Preliminary Product Brief gm5120 gm5115 Product Family On-chip Microcontroller (OCM) Firmware Configurations gm5115 Product Family Support for Standard RGB (sRGB) gm5115 Theory of Operation gm5115 Register Listing gm5115 Input Processing Programming Guide Reference design documents B0108-GUD-01 5110RD1 Reference Design Users Guide B0108-SCH-01 5110RD1 Reference Design Schematics B0108-BOM-01 5110RD1 Reference Design Bill of Materials Firmware / tools documents B0092-SWT-01 gm5115 Product Family Firmware Theory of Operation for Full Custom Configuration B0092-SUG-01 gm5115 Product Family Firmware User Guide for Full-Custom B0092-PRN-01 gm5115 Product Family Firmware Release Notes for Full-Custom B0108-SUG-01 gm5115 Product Family Firmware User Guide for Standalone B0108-PRN-01 gm5115 Product Family Firmware Release Notes for Standalone S0006-GUD-01 G-Probe Debug Software User Guide S0014-GUD-01 G-Wizard Software User Guide Trademarks: RealColor, Real Recovery, and Ultra-Reliable DVI are trademarks of Genesis Microchip Inc. © Copyright 2001, Genesis Microchip Inc. All Rights Reserved. *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Genesis Microchip Inc. reserves the right to change or modify the information contained herein without notice. Please obtain the most recent revision of this document. Genesis Microchip Inc. makes no warranty for the use of its products and bears no responsibility for any errors or omissions that may appear in this document. *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Table Of Contents 1. Overview ............................................................................................................................................ 1 1.1 gm5110/20 System Design Example ........................................................................................... 1 1.2 gm5110/20 Features..................................................................................................................... 2 2. gm5110/20 Pinout .............................................................................................................................. 3 3. gm5110/20 Pin List ............................................................................................................................ 4 4. Functional Description ..................................................................................................................... 10 4.1 Clock Generation ....................................................................................................................... 10 4.1.1 Using the Internal Oscillator with External Crystal............................................................ 11 4.1.2 Using an External Clock Oscillator .................................................................................... 13 4.1.3 Clock Synthesis................................................................................................................... 14 4.2 Hardware Reset .......................................................................................................................... 16 4.3 Analog to Digital Converter....................................................................................................... 16 4.3.1 ADC Pin Connection .......................................................................................................... 17 4.3.2 ADC Characteristics ........................................................................................................... 17 4.3.3 Clock Recovery Circuit ...................................................................................................... 18 4.3.4 Sampling Phase Adjustment ............................................................................................... 19 4.3.5 ADC Capture Window........................................................................................................ 19 4.4 DVI Receiver Block................................................................................................................... 20 4.4.1 DVI Receiver Characteristics ............................................................................................. 20 4.4.2 DVI Capture Window ......................................................................................................... 21 4.4.3 HDCP (High-Bandwidth Digital Content Protection) ........................................................ 21 4.5 Test Pattern Generator (TPG) .................................................................................................... 21 4.6 Input Format Measurement........................................................................................................ 22 4.6.1 HSYNC / VSYNC Delay.................................................................................................... 22 4.6.2 Horizontal and Vertical Measurement ................................................................................ 23 4.6.3 Format Change Detection ................................................................................................... 23 4.6.4 Watchdog ............................................................................................................................ 24 4.6.5 Internal Odd/Even Field Detection (For Interlaced Inputs to ADC Only).......................... 24 4.6.6 Input Pixel Measurement .................................................................................................... 24 4.6.7 Image Phase Measurement ................................................................................................. 24 4.6.8 Image Boundary Detection ................................................................................................. 25 4.6.9 Image Auto Balance............................................................................................................ 25 4.7 RealColorTM Digital Color Controls .......................................................................................... 25 4.7.1 RealColor™ Flesh tone Adjustment ................................................................................... 25 4.7.2 Color Standardization and sRGB Support .......................................................................... 26 4.8 High-Quality Scaling ................................................................................................................. 26 4.8.1 Variable Zoom Scaling ....................................................................................................... 26 June 2002 iii C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.8.2 Horizontal and Vertical Shrink ........................................................................................... 26 4.8.3 Moiré Cancellation ............................................................................................................. 27 4.9 Bypass Options .......................................................................................................................... 27 4.10 Gamma LUT ............................................................................................................................ 27 4.11 Display Output Interface.......................................................................................................... 27 4.11.1 Display Synchronization................................................................................................... 27 4.11.2 Programming the Display Timing .................................................................................... 28 4.11.3 Panel Power Sequencing (PPWR, PBIAS) ....................................................................... 29 4.11.4 Output Dithering ............................................................................................................... 30 4.12 Energy Spectrum Management (ESM) .................................................................................... 30 4.13 OSD.......................................................................................................................................... 30 4.13.1 On-Chip OSD SRAM ....................................................................................................... 31 4.13.2 Color Look-up Table (LUT) ............................................................................................. 32 4.14 On-Chip Microcontroller (OCM)............................................................................................. 32 4.14.1 Standalone Configuration ................................................................................................. 33 4.14.2 Full-Custom Configuration............................................................................................... 34 4.14.3 General Purpose Inputs and Outputs (GPIO’s)................................................................. 35 4.15 Bootstrap Configuration Pins................................................................................................... 35 4.16 Host Interface........................................................................................................................... 36 4.16.1 Host Interface Command Format...................................................................................... 37 4.16.2 2-wire Serial Protocol ....................................................................................................... 37 4.17 Miscellaneous Functions.......................................................................................................... 39 4.17.1 Low Power State............................................................................................................... 39 4.17.2 Pulse Width Modulation (PWM) Back Light Control ...................................................... 39 5. Electrical Specifications ................................................................................................................... 40 5.1 Preliminary DC Characteristics ................................................................................................. 40 5.2 Preliminary AC Characteristics ................................................................................................. 41 6. Ordering Information ....................................................................................................................... 43 7. Mechanical Specifications................................................................................................................ 44 June 2002 iv C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet List Of Tables Table 1. Table 2. Table 3. Table 4. Table 5. Table 6. Table 7. Table 8. Table 9. Table 10. Table 11. Table 12. Table 13. Table 14. Table 15. Table 16. Table 17. Table 18. Table 19. Table 20. Table 21. Table 22. Table 23. Table 24. June 2002 Analog Input Port...................................................................................................4 DVI Input Port .......................................................................................................5 RCLK PLL Pins .....................................................................................................5 Analog HSYNC/VSYNC Inputs............................................................................6 System Interface and GPIO Signals.......................................................................6 Display Output Port ...............................................................................................7 Parallel ROM Interface Port ..................................................................................8 Reserved Pins.........................................................................................................8 Power Pins for ADC Sampling Clock DDS ..........................................................9 Power Pins for Display Clock DDS.......................................................................9 I/O Power and Ground Pins ...................................................................................9 Core Power and Ground Pins.................................................................................9 TCLK Specification .............................................................................................14 Pin Connection for RGB Input with HSYNC/VSYNC .......................................17 ADC Characteristics ............................................................................................18 DVI Receiver Characteristics ..............................................................................20 gm5110/20 GPIOs and Alternate Functions ........................................................35 Bootstrap Signals .................................................................................................36 Instruction Byte Map ...........................................................................................37 Absolute Maximum Ratings ................................................................................40 DC Characteristics ...............................................................................................41 Maximum Speed of Operation.............................................................................42 Display Timing and DCLK Adjustments ............................................................42 2-Wire Host Interface Port Timing ......................................................................42 v C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet List Of Figures Figure 1. Figure 2. Figure 3. Figure 4. Figure 5. Figure 6. Figure 7. Figure 8. Figure 9. Figure 10. Figure 11. Figure 12. Figure 13. Figure 14. Figure 15. Figure 16. Figure 17. Figure 18. Figure 19. Figure 20. Figure 21. Figure 22. Figure 23. Figure 24. Figure 25. Figure 26. Figure 27. Figure 28. Figure 29. Figure 30. June 2002 gm5110/20 System Design Example .....................................................................1 gm5110/20 Pin Out Diagram .................................................................................3 gm5110/20 Functional Block Diagram................................................................10 Using the Internal Oscillator with External Crystal.............................................11 Internal Oscillator Output ....................................................................................12 Sources of Parasitic Capacitance .........................................................................13 Using an External Single-ended Clock Oscillator ...............................................14 Internally Synthesized Clocks..............................................................................15 On-chip Clock Domains ......................................................................................16 Example ADC Signal Terminations.....................................................................17 gm5110/20 Clock Recovery.................................................................................18 ADC Capture Window .........................................................................................19 Some of gm5110/20 built-in test patterns ............................................................21 HSYNC Delay......................................................................................................22 Active Data Crosses HSYNC Boundary ..............................................................23 ODD/EVEN Field Detection................................................................................24 RealColorTM Digital Color Controls.....................................................................25 Display Windows and Timing..............................................................................28 Single Pixel Width Display Data..........................................................................29 Double Pixel Wide Display Data .........................................................................29 Panel Power Sequencing ......................................................................................29 OSD Cell Map ......................................................................................................31 OCM Full-Custom and Standalone Configurations .............................................32 Programming OCM in Standalone Configuration................................................33 Programming the OCM in Full-Custom Configuration .......................................34 Factory Calibration and Test Environment ..........................................................36 2-Wire Protocol Data Transfer .............................................................................38 2-Wire Write Operations (0x1x and 0x2x)...........................................................38 2-Wire Read Operation (0x9x and 0xAx) ............................................................39 gm5110/gm5120 208-pin PQFP Mechanical Drawing .......................................44 vi C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 1. OVERVIEW The gm5110/20 is a graphics processing IC for Liquid Crystal Display (LCD) monitors at XGA/SXGA resolution. It provides all key IC functions required for the highest quality LCD monitors. On-chip functions include a high-speed triple-ADC and PLL, Ultra-Reliable DVI TM receiver, a high quality zoom and shrink scaling engine, an on-screen display (OSD) controller, digital color controls and an on-chip microcontroller (OCM). With this level of integration, the gm5110/20 devices simplify and reduce the cost of LCD monitors while maintaining a high-degree of flexibility and quality. 1.1 gm5110/20 System Design Example Figure 1 below shows a typical dual interface LCD monitor system based on the gm5110/20. Designs based on the gm5110/20 have reduced system cost, simplified hardware and firmware design and increased reliability because only a minimal number of components are required in the system. Analog RGB LCD Module gm5110 / gm5120 DVI Back-light NVRAM Figure 1. June 2002 EEPROM (optional) gm5110/20 System Design Example 1 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 1.2 gm5110/20 Features FEATURES • • • • • • • • • • • • Zoom (from VGA) and shrink (from UXGA) scaling Integrated 8-bit triple-channel ADC / PLL Integrated Ultra-Reliable DVI 1.0-compliant receiver High-Bandwidth Digital Content Protection (HDCP) Embedded microcontroller with parallel ROM interface On-chip versatile OSD engine All system clocks synthesized from a single external crystal Programmable gamma correction (CLUT) RealColor controls provide sRGB compliance PWM back light intensity control 5-Volt tolerant inputs Low EMI and power saving features • High-Quality Advanced Scaling • • • • • Auto-Configuration / Auto-Detection • • • • • • On-chip RAM for downloadable menus 1, 2 and 4-bit per pixel character cells Horizontal and vertical stretch of OSD menus Blinking, transparency and blending On-chip Microcontroller • • • • • Requires no external micro-controller External parallel ROM interface allows firmware customization with little additional cost 21 general-purpose inputs/outputs (GPIO's) available for managing system devices (keypad, back-light, NVRAM, etc) Industry-standard firmware embedded on-chip, requires no external ROM (configuration settings stored in NVRAM) Programmable Output Format • • • Single / double wide up to XGA 75Hz output for gm5110 and up to SXGA 75Hz output for gm5120 Pin swap, odd / even swap and red / blue group swap of RGB outputs for flexibility in board layout Support for 8 or 6-bit panels (with high-quality dithering) • Highly Integrated System-on-a-Chip Reduces Component Count for Highly Cost Effective Solution • Stand-alone operation requires no external ROM and no firmware development for Fast Time to Market Input format detection Phase and image positioning Ultra-Reliable DVI Compliant Input Port • • Supports up to 162MHz (SXGA 75Hz / UXGA 60Hz) On-chip high-performance PLLs (only a single reference crystal required) On-chip OSD Controller • • • • Analog RGB Input Port • • • Fully programmable zoom ratios High-quality shrink capability from UXGA resolution Real Recovery function provides full color recovery image for refresh rates higher than those supported by the LCD panel Moire cancellation • Operating up to 165 MHz (up to UXGA 60Hz) Direct connect to all DVI compliant digital transmitters High-bandwidth Digital Content Protection (HDCP) • Pin and register compatible Family of Products: - gm5110/gm5120 Dual-Interface XGA/SXGA - gm3110/gm3120 Digital-Interface XGA/SXGA - gm2110/gm2120 Analog-Interface XGA/SXGA RealColor Technology • • • • Digital brightness and contrast controls TV color controls including hue and saturation controls Flesh-tone adjustment Full color matrix allows end-users to experience the same colors as viewed on CRTs and other displays (e.g. sRGB compliance) June 2002 2 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 2. GM5110/20 PINOUT gm5110 and gm5120 are pin-compatible. These devices are available in a 208-pin Plastic Quad Flat Pack (PQFP) package. Figure 2 provides the pin locations for all signals. gm5110/20 Pin Out Diagram 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 68 69 70 71 72 73 74 75 76 77 78 79 80 81 82 83 84 85 86 87 88 89 90 91 92 93 94 95 96 97 98 99 100 101 102 103 104 156 155 154 153 152 151 150 149 148 147 146 145 144 143 142 141 140 139 138 137 136 135 134 133 132 131 130 129 128 127 126 125 124 123 122 121 120 119 118 117 116 115 114 113 112 111 110 109 108 107 106 105 GND1_ADC VDD1_ADC_2.5 GND2_ADC VDD2_ADC_2.5 TCLK XTAL AVDD_RPLL AVSS_RPLL VDD_RPLL VSS_RPLL AVDD_DDDS AVSS_DDDS VDD_DDDS VSS_DDDS N/C AVDD_SDDS AVSS_SDDS VDD_SDDS VSS_SDDS HSYNC VSYNC CVSS CVDD_2.5 CVSS Reserved Reserved RVSS RVDD N/C N/C GP07 GP06 GP05 GP04 GP03 GP02 GP01 GP00 DCLK DVS DHS DEN PBIAS PPWR RVSS RVDD PD47/OB7 PD46/OB6 PD45/OB5 PD44/OB4 PD43/OB3 PD42/OB2 RVDD RVSS PD0/ER0 PD1/ER1 PD2/ER2 PD3/ER3 PD4/ER4 PD5/ER5 PD6/ER6 PD7/ER7 PD8/EG0 PD9/EG1 PD10/EG2 PD11/EG3 RVDD RVSS PD12/EG4 PD13/EG5 PD14/EG6 PD15/EG7 PD16/EB0 PD17/EB1 PD18/EB2 PD19/EB3 PD20/EB4 PD21/EB5 PD22/EB6 PD23/EB7 RVDD RVSS PD24/OR0 PD25/OR1 PD26/OR2 PD27/OR3 PD28/OR4 CVDD_2.5 CVSS PD29/OR5 PD30/OR6 PD31/OR7 PD32/OG0 PD33/OG1 PD34/OG2 PD35/OG3 RVDD RVSS PD36/OG4 PD37/OG5 PD38/OG6 PD39/OG7 PD40/OB0 PD41/OB1 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 gm5110/20 GPIO17 RVDD RVSS GPIO21/IRQn RESETn GPIO14/DDC_SCL GPIO15/DDC_SDA ROM_ADDR15 ROM_ADDR14 ROM_ADDR13 ROM_ADDR12 ROM_ADDR11 ROM_ADDR10 ROM_ADDR9 ROM_ADDR8 ROM_ADDR7 ROM_ADDR6 ROM_ADDR5 ROM_ADDR4 RVDD RVSS ROM_ADDR3 ROM_ADDR2 ROM_ADDR1 ROM_ADDR0 CVDD_2.5 CVSS GPI7/ROM_DATA7 GPI6/ROM_DATA6 GPI5/ROM_DATA5 GPI4/ROM_DATA4 GPI3/ROM_DATA3 GPI2/ROM_DATA2 GPI1/ROM_DATA1 GPI0/ROM_DATA0 ROM_Oen RVDD RVSS GPIO8/IRQINn GPIO0/PWM0 GPIO1/PWM1 GPIO2/PWM2 GPIO3/TIMER1 GPIO4/UART_D1 GPIO5/UART_D0 GPIO6 GPIO7 GPIO9 GPIO10 GPIO11/ROM_WEn GPIO12/NVRAM_SDA GPIO13/NVRAM_SCL 208 207 206 205 204 203 202 201 200 199 198 197 196 195 194 193 192 191 190 189 188 187 186 185 184 183 182 181 180 179 178 177 176 175 174 173 172 171 170 169 168 167 166 165 164 163 162 161 160 159 158 157 GPIO18 GPIO19 GPIO20 GPIO16/HFSn GPIO22/HCLK CVDD_2.5 CVSS CLKOUT N/C VDD_RXPLL_2.5 AGND_RXPLL AGND_RXC AVDD_RXC RXCRXC+ AVDD_RX0 RX0RX0+ AGND_RX0 GND_RX0 VDD_RX0_2.5 AVDD_RX1 RX1RX1+ AGND_RX1 GND_RX1 VDD_RX1_2.5 AVDD_RX2 RX2RX2+ AGND_RX2 GND_RX2 VDD_RX2_2.5 AGND_IMB REXT AVDD_IMB AVDD_RED RED+ REDAGND_RED AVDD_GREEN GREEN+ GREENAGND_GREEN AVDD_BLUE BLUE+ BLUEAGND_BLUE AVDD_ADC ADC_TEST AGND_ADC SGND_ADC Figure 2. June 2002 3 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 3. GM5110/20 PIN LIST I/O Legend: A = Analog, I = Input, O = Output, P = Power, G= Ground Table 1. Pin Name No. I/O Description Analog power (3.3V) for the red channel. Must be bypassed with decoupling capacitor to AGND_RED pin on system board (as close as possible to the pin). Positive analog input for Red channel. Negative analog input for Red channel. Analog ground for the red channel. Must be directly connected to the analog system ground plane. Analog power (3.3V) for the green channel. Must be bypassed with decoupling capacitor to AGND_GREEN pin on system board (as close as possible to the pin). Positive analog input for Green channel. Negative analog input for Green channel. Analog ground for the green channel. Must be directly connected to the analog system ground plane. Analog power (3.3V) for the blue channel. Must be bypassed with decoupling capacitor to AGND_BLUE pin on system board (as close as possible to the pin). Positive analog input for Blue channel. Negative analog input for Blue channel. Analog ground for the blue channel. Must be directly connected to the analog system ground plane. Analog power (3.3V) for ADC analog blocks that are shared by all three channels. Includes band gap reference, master biasing and full-scale adjust. Must be bypassed with decoupling capacitor to AGND_ADC pin on system board (as close as possible to the pin). Analog test output for ADC Do not connect. Analog ground for ADC analog blocks that are shared by all three channels. Includes band gap reference, master biasing and full-scale adjust. Must be directly connected to analog system ground plane. Dedicated pad for substrate guard ring that protects the ADC reference system. Must be directly connected to the analog system ground plane. Digital GND for ADC clocking circuit. Must be directly connected to the digital system ground plane Digital power (2.5V) for ADC encoding logic. Must be bypassed with decoupling capacitor to GND1_ADC pin on system board (as close as possible to the pin). Digital GND for ADC clocking circuit. Must be directly connected to the digital system ground plane. Digital power (2.5V) for ADC encoding logic. Must be bypassed with decoupling capacitor to GND2_ADC pin on system board (as close as possible to the pin). AVDD_RED 172 AP RED+ REDAGND_RED 171 170 169 AI AI AG AVDD_GREEN 168 AP GREEN+ GREENAGND_GREEN 167 166 165 AI AI AG AVDD_BLUE 164 AP BLUE+ BLUEAGND_BLUE 163 162 161 AI AI AG AVDD_ADC 160 AP ADC_TEST AGND_ADC 159 158 AO AG SGND_ADC 157 AG GND1_ADC 156 G VDD1_ADC_2.5 155 P GND2_ADC 154 G VDD2_ADC_2.5 153 P June 2002 Analog Input Port 4 C5110-DAT-01C *** Genesis Microchip Confidential *** Table 2. Pin Name 173 AP REXT 174 AI AGND_IMB 175 AG VDD_RX2_2.5 176 P GND_RX2 177 G AGND_RX2 178 AG RX2+ RX2AVDD_RX2 179 180 181 AI AI AP VDD_RX1_2.5 182 P GND_RX1 183 G AGND_RX1 184 AG RX1+ RX1AVDD_RX1 185 186 187 AI AI AP VDD_RX0_2.5 188 P GND_RX0 189 G AGND_RX0 190 AG RX0+ RX0AVDD_RX0 191 192 193 AI AI AP RXC+ RXCAVDD_RXC 194 195 196 AI AI AP AGND_RXC 197 AG GND_RXPLL 198 G VDD_RXPLL_2.5 199 AP CLKOUT 201 AO Analog VDD (3.3V) for internal biasing circuits. Must be bypassed with decoupling capacitors (as close as possible to the pin). External reference resistor. An external 1Kohm (1%) resistor should be connected from this pin to AVDD_IMB pin. Analog GND for internal biasing circuits. Must be connected directly to the ground plane. VDD (2.5V) for DVI input pair 2 logic circuits. Must be bypassed with decoupling capacitor to GND_RX2 pin (as close as possible to the pin). GND for DVI input pair 2 logic circuits. Must be connected directly to the ground plane. Analog GND for DVI input pair 2 input buffer. Must be connected directly to the analog ground plane. DVI input pair 2 DVI input pair 2 Analog VDD (3.3V) for DVI input pair 2 input buffer. Must be bypassed with decoupling capacitor to AGND_RX2 pin (as close as possible to the pin). VDD (2.5V) for DVI input pair 1 logic circuits. Must be bypassed with decoupling capacitor to GND_RX1 pin (as close as possible to the pin). GND for DVI input pair 1 input buffer. Must be connected directly to the analog ground plane. Analog GND for DVI input pair 1 input buffer. Must be connected directly to the analog ground plane. DVI input pair 1 DVI input pair 1 Analog VDD (3.3V) for DVI input pair 1 input buffer. Must be bypassed with decoupling capacitor to AGND_RX1 pin (as close as possible to the pin). VDD (2.5V) for DVI input pair 0 logic circuits. Must be bypassed with decoupling capacitor to GND_RX0 pin (as close as possible to the pin). GND for DVI input pair 0 logic circuits. Must be connected directly to the ground plane. Analog GND for DVI input pair 0 input buffer. Must be connected directly to the analog ground plane. DVI input pair 0 DVI input pair 0 Analog VDD (3.3V) for DVI input pair 0 input buffer. Must be bypassed with decoupling capacitor to AGND_RX0 pin (as close as possible to the pin). DVI input clock pair DVI input clock pair Analog VDD (3.3V) for DVI input clock pair input buffer. Must be bypassed with 100pF capacitor to AGND_RXC pin (as close as possible to the pin). Analog GND for DVI input clock pair input buffer. Must be connected directly to the analog ground plane. Digital GND for the DVI receiver internal PLL. Must be connected directly to the system ground plane. Analog VDD (2.5V) for the DVI receiver internal PLL. Must be bypassed with a decoupling capacitor to AGND_RXPLL pin (as close as possible to the pin). For test purposes only. Do not connect. Table 3. RCLK PLL Pins No I/O Description AVDD_RPLL 150 AP AVSS_RPLL 149 AG TCLK 152 AI XTAL VDD_RPLL VSS_RPLL 151 148 147 AO P G June 2002 DVI Input Port No I/O Description AVDD_IMB Pin Name gm5110/20 Preliminary Data Sheet Analog power for the Reference DDS PLL. Connect to 3.3V supply. Must be bypassed with a 0.1uF capacitor to pin AVSS_RPLL (as close to the pin as possible). Analog ground for the Reference DDS PLL. Must be directly connected to the analog system ground plane. Reference clock (TCLK) from the 14.3MHz crystal oscillator, or from single-ended CMOS/TTL clock oscillator (refer to Figure 7). This is a 5V-tolerant input. Crystal oscillator output. Digital power for RCLK PLL. Connect to 3.3V supply. Digital ground for RCLK PLL. 5 C5110-DAT-01C *** Genesis Microchip Confidential *** Table 4. Pin Name 137 I VSYNC 136 I ADC input horizontal sync input. [Input, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] ADC input vertical sync input. [Input, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] Table 5. System Interface and GPIO Signals No I/O Description RESETn 5 I GPIO0/PWM0 40 IO GPIO1/PWM1 41 IO GPIO2/PWM2 42 IO GPIO3/TIMER1 43 IO GPIO4/UART_DI 44 IO GPIO5/UART_DO 45 IO GPIO6 46 IO GPIO7 47 IO GPIO8/IRQINn 39 IO GPIO9 48 IO GPIO10 49 IO GPIO11/ROM_WEn 50 IO GPIO12/NVRAM_SDA GPIO13/NVRAM_SCL 51 52 IO IO GPIO14/DDC_SCL GPIO15/DDC_SDA GPIO16/HFSn 6 7 205 I IO IO GPIO17 GPIO18 GPIO19 GPIO20 GPIO21/IRQn 1 208 207 206 4 IO IO IO IO IO GPIO22/HCLK 204 IO GPO0 GPO1 GPO2 GPO3 GPO4 GPO5 GPO6 GPO7 119 120 121 122 123 124 125 126 O O O O O O O O June 2002 Analog HSYNC/VSYNC Inputs No I/O Description HSYNC Pin Name gm5110/20 Preliminary Data Sheet Active-low hardware reset signal. The reset signal must be held low for at least 1µS. [Input, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal or PWM0. Open drain option via register setting. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal or PWM1. Open drain option via register setting. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal or PWM2. Open drain option via register setting. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. Open drain option via register setting. This pin is also connected to Timer 1 clock input of the OCM. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. Open drain option via register setting. This pin is also connected to the OCM UART data input signal by programming an OCM register. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. Open drain option via register setting. This pin is also connected to the OCM UART data output signal by programming an OCM register. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. This is also active-low interrupt input to OCM and is directly wired to OCM int_0n. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. Open drain option via register setting. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal. Open drain option via register setting. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output or PROM write enable signal. Open drain option via register setting. [Bi-directional Input, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output or master 2-wire serial interface to NVRAM in standalone operation. Open drain option via register setting. [Bi-directional Input, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] DDC Interface for DVI-HDCP communication. This is 5V-tolerant SCL pin. DDC Interface for DVI-HDCP communication. This is 5V-tolerant SDA pin. General-purpose input/output signal when host interface is disabled, or host interface framing signal. [Bi-directional, Schmitt trigger (400mV typical hysteresis), slew rate limited, 5V tolerant] General-purpose input/output signal. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose input/output signal when host port is disabled, or active-low and opendrain interrupt output pin. [Bi-directional, 5V-tolerant] General-purpose input/output signal when host interface is disabled, or host clock signal. [Bi-directional, Schmitt trigger (400mV typical hysteresis), 5V-tolerant] General-purpose output signals. 6 C5110-DAT-01C *** Genesis Microchip Confidential *** Table 6. Pin Name Display Output Port No I/O Description DCLK 118 O DVS 117 O DHS 116 O DEN 115 O PBIAS 114 O PPWR 113 O PD47 PD46 PD45 PD44 PD43 PD42 PD41 PD40 PD39 PD38 PD37 PD36 PD35 PD34 PD33 PD32 PD31 PD30 PD29 PD28 PD27 PD26 PD25 PD24 PD23 PD22 PD21 PD20 PD19 PD18 PD17 PD16 PD15 PD14 PD13 PD12 PD11 PD10 PD9 PD8 PD7 PD6 PD5 PD4 PD3 PD2 PD1 PD0 110 109 108 107 106 105 104 103 102 101 100 99 96 95 94 93 92 91 90 87 86 85 84 83 80 79 78 77 76 75 74 73 72 71 70 69 66 65 64 63 62 61 60 59 58 57 56 55 O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O O June 2002 gm5110/20 Preliminary Data Sheet Panel output clock. [Tri-state output, Programmable Drive] Panel Vertical Sync. [Tri-state output, Programmable Drive] Panel Horizontal Sync. [Tri-state output, Programmable Drive] Panel Display Enable, which frames the output background. [Tri-state output, Programmable Drive] Panel Bias Control (back light enable) [Tri-state output, Programmable Drive] Panel Power Control [Tri-state output, Programmable Drive] Panel output data. [Tri-state output, Programmable Drive] 7 C5110-DAT-01C *** Genesis Microchip Confidential *** Table 7. Pin Name ROM_ADDR15 ROM_ADDR14 ROM_ADDR13 ROM_ADDR12 ROM_ADDR11 ROM_ADDR10 ROM_ADDR9 ROM_ADDR8 ROM_ADDR7 ROM_ADDR6 ROM_ADDR5 ROM_ADDR4 ROM_ADDR3 ROM_ADDR2 ROM_ADDR1 ROM_ADDR0 GPI7/ROM_DATA7 GPI6/ROM_DATA6 GPI5/ROM_DATA5 GPI4/ROM_DATA4 GPI3/ROM_DATA3 GPI2/ROM_DATA2 GPI1/ROM_DATA1 GPI0/ROM_DATA0 ROM_OEn Parallel ROM Interface Port No I/O Description 8 9 10 11 12 13 14 15 16 17 18 19 22 23 24 25 28 29 30 31 32 33 34 35 36 IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO IO I I I I I I I I O ROM address output. These pins also serve as 5V-tolerant bootstrap inputs on power up. 5V-tolerant external PROM data input, or general-purpose input in standalone operation. External PROM data Output Enable Table 8. Pin Name N/C N/C Reserved Reserved N/C N/C June 2002 gm5110/20 Preliminary Data Sheet Reserved Pins No I/O Description 127 128 131 132 142 200 O O I I O O No connect. No connect. Tie to GND. Tie to GND. No connect. No connect. 8 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Note that VDD pins having "_2.5" in their names should be connected to 2.5V power supplies. All other VDD pins should be connected to 3.3V power supplies. Table 9. Pin Name Power Pins for ADC Sampling Clock DDS No I/O Description AVDD_DDDS 146 AP AVSS_DDDS 145 AG VDD_DDDS VSS_DDDS 144 143 P G Analog power for the Destination DDS. Connect to 3.3V supply. Must be bypassed with a 0.1uF capacitor to AVSS_DDDS pin (as close to the pin as possible). Analog ground for the Destination DDS. Must be directly connected to the analog system ground. Digital power for the Destination DDS. Connect to 3.3V supply. Digital ground for the Destination DDS. Table 10. Power Pins for Display Clock DDS Pin Name No I/O Description AVDD_SDDS 141 AP AVSS_SDDS 140 AG VDD_SDDS VSS_SDDS 139 138 P G Analog power for Source DDS. Connect to 3.3V supply. Must be bypassed with a 0.1uF capacitor to AVSS_SDDS pin (as close to the pin as possible). Analog ground for Source DDS. Must be directly connected to the analog system ground plane. Digital power for the Source DDS. Connect to 3.3V supply. Digital ground for the Source DDS. Table 11. I/O Power and Ground Pins Pin Name RVDD RVSS No I/O Description 2 20 37 53 67 81 97 111 129 3 21 38 54 68 82 98 112 130 P P P P P P P P P G G G G G G G G G Connect to 3.3V supply. Must be bypassed with a 0.1uF capacitor to RVSS (as close to the pin as possible). Connect to digital ground. Table 12. Core Power and Ground Pins Pin Name CVDD_2.5 CVSS June 2002 No I/O Description 26 88 134 203 27 89 133 135 202 P P P P G G G G G Connect to 2.5V supply. Must be bypassed with a 0.1uF capacitor to CVSS (as close to the pin as possible). Connect to digital ground. 9 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4. FUNCTIONAL DESCRIPTION A functional block diagram is illustrated below. Each of the functional units shown is described in the following sections. NVRAM Serial I/F Serial Host I/F Parallel ROM IF Crystal Reference GPIO Host Interface 8051-style Microcontroller MCU RAM DVI-Compliant DVI Input Clock Generation OSD Controller OSD RAMs Internal ROM DVI Rx HDCP Analog RGB External ROM I/F Image Capture / Measurement Triple ADC Figure 3. Brightness / Contrast / Hue / Sat / RealColorTM / Moire Zoom / Shrink / Filter Gamma Control Output Data Path Panel Data and Control gm5110/20 Functional Block Diagram 4.1 Clock Generation The gm5110/20 features three clock inputs. All additional clocks are internal clocks derived from one or more of these: 1. Crystal Input Clock (TCLK and XTAL). This is the input pair to an internal crystal oscillator and corresponding logic. A 14.3 MHz TV crystal is recommended. Other crystal frequencies may be used, but require custom programming. This is illustrated in Figure 4 below. Alternatively, a single-ended TTL/CMOS clock oscillator can be driven into the TCLK pin (leave XTAL as N/C in this case). This is illustrated in Figure 7 below. This option is selected by connecting a 10KΩ pull-up to ROM_ADDR13 (refer to Table 18). See also Table 14. 2. DVI Differential Input Clock (RC+ and RC-) 3. Host Interface Transfer Clock (HCLK) June 2002 10 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet The gm5110/20 TCLK oscillator circuitry is a custom designed circuit to support the use of an external oscillator or a crystal resonator to generate a reference frequency source for the gm5110/20 device. 4.1.1 Using the Internal Oscillator with External Crystal The first option for providing a clock reference is to use the internal oscillator with an external crystal. The oscillator circuit is designed to provide a very low jitter and very low harmonic clock to the internal circuitry of the gm5110/20. An Automatic Gain Control (AGC) is used to insure startup and operation over a wide range of conditions. The oscillator circuit also minimizes the overdrive of the crystal, which reduces the aging of the crystal. When the gm5110/20 is in reset, the state of the ROM_ADDR13 pin (pin number 10) is sampled. If the pin is left unconnected (internal pull-down) then internal oscillator is enabled. In this mode a crystal resonator is connected between TCLK (pin 152) and the XTAL (pin 151) with the appropriately sized loading capacitors CL1 and CL2. The size of CL1 and CL2 are determined from the crystal manufacturer’s specification and by compensating for the parasitic capacitance of the gm5110/20 device and the printed circuit board traces. The loading capacitors are terminated to the analog VDD power supply. This connection increases the power supply rejection ratio when compared to terminating the loading capacitors to ground. gm5115 Vdda CL1 152 Vdd TCLK 151 Vdda XTAL CL2 OSC_OUT TCLK Distribution 100 K 180 uA 10 N/C Reset State Logic ROM_ADDR13 Internal Oscillator Enable Internal Pull Down Resistor ~ 60K Figure 4. June 2002 Using the Internal Oscillator with External Crystal 11 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet The TCLK oscillator uses a Pierce Oscillator circuit. The output of the oscillator circuit, measured at the TCLK pin, is an approximate sine wave with a bias of about 2 volts above ground (see Figure 5). The peak-to-peak voltage of the output can range from 250 mV to 1000 mV depending on the specific characteristics of the crystal and variation in the oscillator characteristics. The output of the oscillator is connected to a comparator that converts the sine wave to a square wave. The comparator requires a minimum signal level of about 50-mV peak to peak to function correctly. The output of the comparator is buffered and then distributed to the gm5110/20 circuits. 3.3 Volts 250 mV peak to peak to 1000 mV peak to peak ~ 2 Volts time Figure 5. Internal Oscillator Output One of the design parameters that must be given some consideration is the value of the loading capacitors used with the crystal as shown in Figure 6. The loading capacitance (Cload) on the crystal is the combination of CL1 and CL2 and is calculated by Cload = ((CL1 * CL2) / (CL1 + CL2)) + Cshunt. The shunt capacitance Cshunt is the effective capacitance between the XTAL and TCLK pins. For the gm5110/20 this is approximately 9 pF. CL1 and CL2 are a parallel combination of the external loading capacitors (Cex), the PCB board capacitance (Cpcb), the pin capacitance (Cpin), the pad capacitance (Cpad), and the ESD protection capacitance (Cesd). The capacitances are symmetrical so that CL1 = CL2 = Cex + CPCB + Cpin + Cpad + CESD. The correct value of Cex must be calculated based on the values of the load capacitances. Approximate values are provided in Figure 6. June 2002 12 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet CL1 = Cex1 + Cpcb + Cpin + Cpad + Cesd Vdda Cex1 Cpcb Cpin 141 Cpad Cesd Internal Oscillator TCLK gm5115 Cshunt Vdda 142 XTAL Cex2 Cpcb Cpin CL2 = Cex1 + Cpcb + Cpin + Cpad + Cesd Figure 6. Cpad Cesd Approximate values: CPCB ~ 2 pF to 10 pF (layout dependent) Cpin ~ 1.1 pF Cpad ~ 1 pF Cesd ~ 5.3 pF Cshunt ~ 9 pF Sources of Parasitic Capacitance Some attention must be given to the details of the oscillator circuit when used with a crystal resonator. The PCB traces should be as short as possible. The value of Cload that is specified by the manufacturer should not be exceeded because of potential start up problems with the oscillator. Additionally, the crystal should be a parallel resonate-cut and the value of the equivalent series resistance must be less then 90 Ohms. 4.1.2 Using an External Clock Oscillator Another option for providing the reference clock is to use a single-ended external clock oscillator. When the gm5110/20 is in reset, the state of the ROM_ADDR13 (pin 10) is sampled. If ROM_ADDR13 is pulled high by connecting to VDD through a pull-up resistor (15KΩ recommended, 15KΩ maximum) then external oscillator mode is enabled. In this mode the internal oscillator circuit is disabled and the external oscillator signal that is connected to the TCLK pin (pin number 152) is routed to an internal clock buffer. This is illustrated in Figure 7. June 2002 13 C5110-DAT-01C *** Genesis Microchip Confidential *** Vdd 14 to 24 MHz gm5110/20 Preliminary Data Sheet gm5110/20 152 Vdd OSC_OUT TCLK Distribution TCLK Oscillator GND 151 Vdd Internal Oscillator XTAL Disable 10 K 10 Reset State Logic External Oscillator Enable ROM_ADDR13 Internal Pull Down Resistor ~ 60 K Figure 7. Using an External Single-ended Clock Oscillator Frequency Jitter Tolerance Rise Time (10% to 90%) Maximum Duty Cycle 14 to 24 MHz 250 ps 5 ns 40-60 Table 13. TCLK Specification 4.1.3 Clock Synthesis The gm5110/20 synthesizes all additional clocks internally as illustrated in Figure 8 below. The synthesized clocks are as follows: 1. Main Timing Clock (TCLK) is the output of the chip internal crystal oscillator. TCLK is derived from the TCLK/XTAL pad input. 2. Reference Clock (RCLK) synthesized by RCLK PLL (RPLL) using TCLK as the reference. 3. DVI Input Clock (DVI_CLK) synthesized by DVI receiver PLL using RC+/RC- pair as the reference. 4. Input Source Clock (SCLK) synthesized by Source DDS (SDDS) PLL using input HSYNC as the reference. The SDDS internal digital logic is driven by RCLK. June 2002 14 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 5. Display Clock (DCLK) synthesized by Destination DDS (DDDS) PLL using IP_CLK as the reference. The DDDS internal digital logic is driven by RCLK. 6. Half Reference Clock (RCLK/2) is the RCLK (see 2, above) divided by 2. Used as OCM_CLK domain driver. 7. Quarter Reference Clock (RCLK/4) is the RCLK (see 2, above) divided by 4. Used as alternative clock (faster than TCLK) to drive IFM. 8. ADC Output Clock (SENSE_ACLK) is a delay-adjusted ADC sampling clock, ACLK. ACLK is derived from SCLK. HSYNC SCLK SDDS IP_CLK TCLK DDDS DCLK RCLK PLL /2 RCLK/2 /4 RCLK/4 RC+ DVI Rx DVI_CLK RC- Figure 8. Internally Synthesized Clocks The on-chip clock domains are selected from the synthesized clocks as shown in Figure 9 below. These include: 1. Input Domain Clock (IP_CLK). Max = 165MHz 2. Host Interface and On-Chip Microcontroller Clock (OCM_CLK). Max = 100MHz 3. Filter and Display Pixel Clock (DP_CLK). Max = 135MHz 4. Source Timing Measurement Domain Clock (IFM_CLK). Max = 50MHz 5. ADC Domain Clock (ACLK). Max = 165MHz. The clock selection for each domain as shown in the figure below is controlled using the CLOCK_CONFIG registers (index 0x03 and 0x04). June 2002 15 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet SCLK DCLK SENSE_ACLK IP_CLK DP_CLK IP_CLK DVI_CLK RCLK/2 SCLK RCLK/4 IFM_CLK OCM_CLK ACLK TCLK TCLK Figure 9. On-chip Clock Domains 4.2 Hardware Reset Hardware Reset is performed by holding the RESETn pin low for a minimum of 1µs. A TCLK input (see Clock Options above) must be applied during and after the reset. When the reset period is complete and RESETn is de-asserted, the power-up sequence is as follows: 1. Reset all registers of all types to their default state (this is 00h unless otherwise specified in the gm5110/20 Register Listing). 2. Force each clock domain into reset. Reset will remain asserted for 64 local clock domain cycles following the de-assertion of RESETn. 3. Operate the OCM_CLK domain at the TCLK frequency. 4. Preset the RCLK PLL to output ~200MHz clock (assumes 14.3MHz TCLK crystal frequency). 5. Wait for RCLK PLL to Lock. Then, switch the OCM_CLK domain to operate from the bootstrap selected clock. 6. If a pull-up resistor is installed on ROM_ADDR9 pin (see Table 18), then the OCM becomes active as soon as OCM_CLK is stable. Otherwise, the OCM remains in reset until OCM_CONTROL register (0x22) bit 1 is enabled. 4.3 Analog to Digital Converter The gm5110/20 chip has three ADC’s (analog-to-digital converters), one for each color (red, green, and blue). June 2002 16 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.3.1 ADC Pin Connection The analog RGB signals are connected to the gm5110/20 as described below: Table 14. Pin Connection for RGB Input with HSYNC/VSYNC Pin Name Red+ RedGreen+ GreenBlue+ BlueHSYNC VSYNC ADC Signal Name Red Terminate as illustrated in Figure 10 Green Terminate as illustrated in Figure 10 Blue Terminate as illustrated in Figure 10 Horizontal Sync (Terminate as illustrated in Figure 10) Vertical Sync (Terminate as with HSYNC illustrated in Figure 10) gm5110/20 100Ω RED RED + 0.01uF 75Ω DB15 100Ω RED - GND 0.01uF HSYNC Figure 10. HS Example ADC Signal Terminations Please note that it is very important to follow the recommended layout guidelines for the circuit shown in Figure 10. These are described in "gm5115 Layout Guidelines" document number C5115-SLG-01A. 4.3.2 ADC Characteristics The table below summarizes the characteristics of the ADC: June 2002 17 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Table 15. ADC Characteristics MIN Track & Hold Amp Bandwidth TYP MAX 290 MHz Full Scale Adjust Range at RGB Inputs Full Scale Adjust Sensitivity Zero Scale Adjust Sensitivity Sampling Frequency (Fs) Differential Non-Linearity (DNL) 0.55 V 0.90 V +/- 1 LSB Measured at ADC Output. Independent of full scale RGB input. Measured at ADC Output. +/- 1 LSB 10 MHz +/-0.5 LSB No Missing Codes Integral Non-Linearity (INL) Channel to Channel Matching NOTE Guaranteed by design. Note that the Track & Hold Amp Bandwidth is programmable. 290 MHz is the maximum setting. 162.5 MHz +/-0.9 LSB Fs = 135 MHz Guaranteed by test. Fs =135 MHz +/- 1.5 LSB +/- 0.5 LSB The gm5110/20 ADC has a built in clamp circuit for AC-coupled inputs. By inserting series capacitors (about 10 nF), the DC offset of an external video source can be removed. The clamp pulse position and width are programmable. 4.3.3 Clock Recovery Circuit The SDDS (Source Direct Digital Synthesis) clock recovery circuit generates the clock used to sample analog RGB data (IP_CLK or source clock). This circuit is locked to HSYNC of the incoming video signal. Patented digital clock synthesis technology makes the gm5110/20 clock circuits resistant to temperature/voltage drift. Using DDS (Direct Digital Synthesis) technology, the clock recovery circuit can generate any IP_CLK clock frequency within the range of 10MHz to 165MHz. Image Phase Measurement R G B ADC 24 Window Capture Phase HSYNC HSYNC (delayed) Figure 11. June 2002 SDDS IPCLK gm5110/20 Clock Recovery 18 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.3.4 Sampling Phase Adjustment The programmable ADC sampling phase is adjusted by delaying the HSYNC input to the SDDS. The accuracy of the sampling phase is checked and the result read from a register. This feature enables accurate auto-adjustment of the ADC sampling phase. 4.3.5 ADC Capture Window Figure 12 below illustrates the capture window used for the ADC input. In the horizontal direction the capture window is defined in IP_CLKs (equivalent to a pixel count). In the vertical direction it is defined in lines. All the parameters beginning with “Source” are programmed gm5110/20 registers values. Note that the input vertical total is solely determined by the input and is not a programmable parameter. Source Horizontal Total (pixels) Reference Point Source Hstart Source Height Input Vertical Total (lines) Source Vstart Source Width Capture Window Figure 12. ADC Capture Window The Reference Point marks the leading edge of the first internal HSYNC following the leading edge of an internal VSYNC. Both the internal HSYNC and the internal VSYNC are derived from external HSYNC and VSYNC inputs. Horizontal parameters are defined in terms of single pixel increments relative to the internal horizontal sync. Vertical parameters are defined in terms of single line increments relative to the internal vertical sync. June 2002 19 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet For ADC interlaced inputs, the gm5110/20 may be programmed to automatically determine the field type (even or odd) from the VSYNC/HSYNC relative timing. See Input Format Measurement, Section 4.5. 4.4 DVI Receiver Block The Ultra-Reliable DVITM receiver block of the gm5110/20 is compliant with DVI1.0 single link specifications. Digital Visual Interface (DVI) is a standard that uses Transition Minimized Differential Signaling protocol (TMDS). This block supports an input clock frequency ranging from 20 MHz to 165 MHz. 4.4.1 DVI Receiver Characteristics Table 16 summarizes the characteristics of the four Receiver Pair inputs. Please note that it is very important to follow the recommended layout guidelines for these signals. These are described in "gm5115 Layout Guidelines" document number C5115-SLG-01A. Table 16. DVI Receiver Characteristics MIN TYP MAX NOTE DC Characteristics Differential Input Voltage Input Common Mode Voltage Behavior when Transmitter Disable Input clock frequency Input differential sensitivity (Peak-to-peak) Max differential input (peak-to-peak) Allowable Intra-Pair skew at Receiver Allowable Inter-Pair skew at Receiver Worst case differential input clock jitter tolerance 150mV AVDD –300m V AVDD -10mV AC Characteristics 20 MHz 150mV 1200mV AVDD -37mV AVDD +10mV 165 MHz 1560 mV 250 ps 4.0 ns 188 ps Input clock = 160 MHz Through register programming, the receiver unit may be placed in one of three states: • Active: The receiver block is fully on and running. • Standby: Only the RC (clock) channel remains active. Data and other control signals are not decoded. • Off: The receiver block is powered down. June 2002 20 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.4.2 DVI Capture Window DE (Display Enable), HSYNC and VSYNC are synthesized internally by examining the active regions of each line and compensating for possible source timing errors and/or embedded HSYNC / VSYNC jitter. There are two ways to define the DVI capture region: CREF Capture - In this mode the usual active window parameters must be programmed as with ADC inputs (see Section 4.3.5.). DE Capture - In this mode the active window code embedded in the DVI signal defines the active window automatically. Only the active width and active length parameters obtained by performing Input Format Measurement (IFM) need be programmed. 4.4.3 HDCP (High-Bandwidth Digital Content Protection) The HDCP system allows authentication of a video receiver by a video transmitter, decryption of transmitter-encoded video data by the receiver, and periodic renew-ability of authentication during transmission. The gm5110/20 implements circuitry to allow full support of the HDCP 1.0 protocol for DVI inputs. For enhanced security, Genesis provides a means of storing and accessing the secret key given to individual monitor units in an encrypted format. To use HDCP it is necessary to obtain the HDCP key encryption tool, called Gencrypt, from Genesis. Gencrypt will only be made available to HDCP licensed customers. Further details of the protocol and theory of the system can be found in the High-bandwidth Digital Content Protection System specification (see www.digital-cp.com). Note that this section applies to the HDCP enabled chip versions gm5110-H and gm5120-H but not the standard versions gm5110 and gm5120. 4.5 Test Pattern Generator (TPG) The gm5110/20 contains hundreds of test patterns, some of which are shown in Figure 13. Once programmed, the gm5110/20 test pattern generator can replace a video source (e.g. a PC) during factory calibration and test. This simplifies the test procedure and eliminates the possibility of image noise being injected into the system from the source. The foreground and background colors are programmable. In addition, the gm5110/20 OSD controller can be used to produce other patterns. Figure 13. June 2002 Some of gm5110/20 built-in test patterns 21 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.6 Input Format Measurement The gm5110/20 has an Input Format Measurement block (the IFM) providing the capability of measuring the horizontal and vertical timing parameters of the input video source. This information may be used to determine the video format and to detect a change in the input format. It is also capable of detecting the field type of interlaced formats. The IFM features a programmable reset, separate from the regular gm5110/20 soft reset. This reset disables the IFM, reducing power consumption. The IFM is capable of operating while gm5110/20 is running in power down mode. Horizontal measurements are measured in terms of the selected IFM_CLK (either TCLK or RCLK/4), while vertical measurements are measured in terms of HSYNC pulses. For an overview of the internally synthesized clocks, see section 4.1. 4.6.1 HSYNC / VSYNC Delay The active input region captured by the gm5110/20 is specified with respect to internal HSYNC and VSYNC. By default, internal syncs are equivalent to the HSYNC and VSYNC at the input pins and thus force the captured region to be bounded by external HSYNC and VSYNC timing. However, the gm5110/20 provides an internal HSYNC and VSYNC delay feature that removes this limitation. This feature is available for use with both the ADC input and the DVI Rx (DE-regeneration mode). By delaying the sync internally, the gm5110/20 can capture data that spans across the sync pulse. It is possible to use HSNYC and VSYNC delay for image positioning. (Alternatively, Source_HSTART and Source_VSTART in Figure 12 are used for image positioning of analog input.) Taken to an extreme, the intentional movement of images across apparent HSYNC and VSYNC boundaries creates a horizontal and/or vertical wrap effect. HSYNC is delayed by a programmed number of selected input clocks. active HS(system) HS(internal) active capture capture programmable delay capture input block actually captures across HSYNC Figure 14. HSYNC Delay Delayed horizontal sync may be used to solve a potential problem with VSYNC jitter with respect to HSYNC. VSYNC and HSYNC are generally driven active coincidentally, but with different paths to the gm5110/20 (HSYNC is often regenerated from a PLL). As a result, VSYNC may be seen earlier or later. Because VSYNC is used to reset the line June 2002 22 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet counter and HSYNC is used to increment it, any difference in the relative position of HSYNC and VSYNC is seen on-screen as vertical jitter. By delaying the HSYNC a small amount, it can be ensured that VSYNC always resets the line counter prior to it being incremented by the “first” HSYNC. active data crosses HS boundary delayed HS placed safely within blanking Data HS (system) Internal Delayed HS Figure 15. Active Data Crosses HSYNC Boundary 4.6.2 Horizontal and Vertical Measurement The IFM is able to measure the horizontal period and active high pulse width of the HSYNC signal, in terms of the selected clock period (either TCLK or RCLK/4.). Horizontal measurements are performed on only a single line per frame (or field). The line used is programmable. It is able to measure the vertical period and VSYNC pulse width in terms of rising edges of HSYNC. Once enabled, measurement begins on the rising VSYNC and is completed on the following rising VSYNC. Measurements are made on every field / frame until disabled. 4.6.3 Format Change Detection The IFM is able to detect changes in the input format relative to the last measurement and then alert both the system and the on-chip microcontroller. The microcontroller sets a measurement difference threshold separately for horizontal and vertical timing. If the current field / frame timing is different from the previously captured measurement by an amount exceeding this threshold, a status bit is set. An interrupt can also be programmed to occur. June 2002 23 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.6.4 Watchdog The watchdog monitors input VSYNC / HSYNC. When any HSYNC period exceeds the programmed timing threshold (in terms of the selected IFM_CLK), a register bit is set. When any VSYNC period exceeds the programmed timing threshold (in terms of HSYNC pulses), a second register bit is set. An interrupt can also be programmed to occur. 4.6.5 Internal Odd/Even Field Detection (For Interlaced Inputs to ADC Only) The IFM has the ability to perform field decoding of interlaced inputs to the ADC. The user specifies start and end values to outline a “window” relative to HSYNC. If the VSYNC leading edge occurs within this window, the IFM signals the start of an ODD field. If the VSYNC leading edge occurs outside this window, an EVEN field is indicated (the interpretation of odd and even can be reversed). The window start and end points are selected from a predefined set of values. HS window Window Start Window End VS - even VS - odd Figure 16. ODD/EVEN Field Detection 4.6.6 Input Pixel Measurement The gm5110/20 provides a number of pixel measurement functions intended to assist in configuring system parameters such as pixel clock, SDDS sample clocks per line and phase setting, centering the image, or adjusting the contrast and brightness. 4.6.7 Image Phase Measurement This function measures the sampling phase quality over a selected active window region. This feature may be used when programming the source DDS to select the proper phase setting. Please refer to the gm5110/20 Programming Guide for the optimized algorithm. June 2002 24 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.6.8 Image Boundary Detection The gm5110/20 performs measurements to determine the image boundary. This information is used when programming the Active Window and centering the image. 4.6.9 Image Auto Balance The gm5110/20 performs measurements on the input data that is used to adjust brightness and contrast. 4.7 RealColorTM Digital Color Controls The gm5110/20 provides high-quality digital color controls. These consist of a subtractive "black level" stage, followed by a full 3x3 RGB matrix multiplication stage, followed by an signed offset stage as shown in Figure 17. Subtractive Offset (Black Level) Red In - Green In - Blue In Figure 17. 3x3 Color Conversion X Additive Offset (Brightness) +/- Red Out +/- Green Out +/- Blue Out RealColorTM Digital Color Controls This structure can accommodate all RGB color controls such as black-level (subtractive stage), contrast (multiplicative stage), and brightness (signed additive offset). In addition, it supports all YUV color controls including brightness (additive factor applied to Y), contrast (multiplicative factor applied to Y), hue (rotation of U and V through an angle) and saturation (multiplicative factor applied to both Y and V). To provide the highest color purity all mathematical functions use 10 bits of accuracy. The final result is then dithered to eight or six bits (as required by the LCD panel). 4.7.1 RealColor™ Flesh tone Adjustment The human eye is more sensitive to variations of flesh tones than other colors; for example, the user may not care if the color of grass is modified slightly during image capture and/or display. However, if skin tones are modified by even a small amount, it is unacceptable. The gm5110/20 features flesh tone adjustment capabilities. This feature is not based on lookup June 2002 25 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet tables, but rather a manipulation of YUV-channel parameters. Flesh tone adjustment is available for all inputs. 4.7.2 Color Standardization and sRGB Support Internet shoppers may be very picky about what color they experience on the display. gm5110/20 RealColorTM digital color controls can be used to make the color response of an LCD monitor compliant with standard color definitions, such as sRGB. sRGB is a standard for color exchange proposed by Microsoft and HP (see www.srgb.com). gm5110/20 RealColor controls can be used to make LCD monitors sRGB compliant, even if the native response of the LCD panel itself is not. For more information on sRGB compliance using gm5110/20 family devices please refer to the sRGB application brief C5115-APB-02A. 4.8 High-Quality Scaling The gm5110/20 zoom scaler uses an adaptive scaling technique proprietary to Genesis Microchip Inc., and provides high quality scaling of real time video and graphics images. An input field/frame is scalable in both the vertical and horizontal dimensions. Interlaced fields may be spatially de-interlaced by vertically scaling and repositioning the input fields to align with the output display’s pixel map. 4.8.1 Variable Zoom Scaling The gm5110/20 scaling filter can combine its advanced scaling with a pixel-replication type scaling function. This is useful for improving the sharpness and definition of graphics when scaling at high zoom factors (such as VGA to XGA). 4.8.2 Horizontal and Vertical Shrink A shrink function may be performed on the input data. This is an arbitrary horizontal active resolution reduction to between (50% + 1 pixel) to 100% of the input. For example, this allows SXGA 1280 pixels to be displayed as 1024 (XGA). The gm5110/20 provides an arbitrary vertical shrink down to (50% + 1 line) of the original image size. Together with the arbitrary horizontal shrink, this allows the gm5110/20 to capture and display images one VESA standard format larger than the native display resolution. For example, SXGA may be captured and displayed on an XGA panel. June 2002 26 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.8.3 Moiré Cancellation The gamma curve and other non-linearities can affect the energy distribution of pixels when scaled to different areas of the screen. This is an example of the Moiré effect. The gm5110/20 has hardware features to negate the Moiré effect, improving the scaling quality. 4.9 Bypass Options The gm5110/20 has the capability to completely bypass internal processing. In this case, captured input signals and data are passed, with a small register latency, straight through to the display output. The gm5110/20 is also able to bypass the zoom filter. 4.10 Gamma LUT The gm5110/20 provides an 8 to 10-bit look-up table (LUT) for each input color channel intended for Gamma correction and to compensate for a non-linear response of the LCD panel. A 10-bit output results in an improved color depth control. The 10-bit output is then dithered down to 8 bits (or 6 bits) per channel at the display (see section 4.11.3 below). The LUT is user programmable to provide an arbitrary transfer function. Gamma correction occurs after the zoom / shrink scaling block. The LUT has bypass enable. If bypassed, the LUT does not require programming. 4.11 Display Output Interface The Display Output Port provides data and control signals that permit the gm5110/20 to connect to a variety of flat panel or CRT devices. The output interface is configurable for 18 or 24-bit RGB pixels, either single or double pixel wide. All display data and timing signals are synchronous with the DCLK output clock. 4.11.1 Display Synchronization Refer to section 4.1 for information regarding internal clock synthesis. The gm5110/20 supports the following display synchronization modes: • • Frame Sync Mode: The display frame rate is synchronized to the input frame or field rate. This mode is used for standard operation. Free Run Mode: No synchronization. This mode is used when there is no valid input timing (i.e. to display OSD messages or a splash screen) or for testing purposes. In June 2002 27 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet free-run mode, the display timing is determined only by the values programmed into the display window and timing registers. 4.11.2 Programming the Display Timing Display timing signals provide timing information so the Display Port can be connected to an external display device. Based on values programmed in registers, the Display Output Port produces the horizontal sync (DHS), vertical sync (DVS), and data enable (DEN) control signals. The figure below provides the registers that define the output display timing. DH_BKGND_START DVS Horizontal values are programmed in single pixel increments relative to the leading edge of the horizontal sync signal. Vertical values are programmed in line increments relative to the leading edge of the vertical sync signal. DH_BKGND_END DV_VS_END VSYNC Region Vertical Blanking (Back Porch) DV_BKGND_START DV_ACTIVE_START DV_TOTAL Display Active Window Horizontal Blanking (Front Porch) Horizontal Blanking (Back Porch) HSYNC region Display Background Window DV_ACTIVE_LENGTH DV_BKGND_END Vertical Blanking (Front Porch) DH_TOTAL DHS DEN ** DH_HS_END ** DEN is not asserted during vertical blanking DH_ACTIVE_WIDTH DH_ACTIVE_START Figure 18. Display Windows and Timing The double-wide output only supports an even number of horizontal pixels. June 2002 28 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet DCLK (Output) DEN (Output) ER/EG/EB (Output) XXX rgb0 OR/OG/OB (Output) Figure 19. rgb1 rgb2 rgb3 rgb4 XXX Single Pixel Width Display Data DCLK (Output) DEN (Output) ER/EG/EB (Output) XXX rgb0 rgb2 rgb4 rgb6 rgb8 OR/OG/OB (Output) XXX rgb1 rgb3 rgb5 rgb7 rgb9 Figure 20. Double Pixel Wide Display Data 4.11.3 Panel Power Sequencing (PPWR, PBIAS) gm5110/20 has two dedicated outputs PPWR and PBIAS (pins 113 and 114) to control LCD power sequencing once data and control signals are stable. The timing of these signals is fully programmable. TMG1 TMG2 <State1> <State2> TMG2 TMG1 PPWR Output Panel Data and Control Signals PBIAS Output <State0> <State3> POWER_SEQ_EN = 1 Figure 21. June 2002 <State2> <State1> <State0> POWER_SEQ_EN = 0 Panel Power Sequencing 29 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.11.4 Output Dithering The Gamma LUT outputs a 10-bit value for each color channel. This value is dithered down to either 8-bits for 24-bit per pixel panels, or 6-bits for 18-bit per pixel panels. The benefit of dithering is that the eye tends to average neighboring pixels and a smooth image free of contours is perceived. Dithering works by spreading the quantization error over neighboring pixels both spatially and temporally. Two dithering algorithms are available: random or ordered dithering. Ordered dithering is recommended when driving a 6-bit panel. All gray scales are available on the panel output whether using 8-bit panel (dithering from 10 to 8 bits per pixel) or using 6-bit panel (dithering from 10 down to 6 bits per pixel). 4.12 Energy Spectrum Management (ESM) High spikes in the EMI power spectrum may cause LCD monitor products to violate emissions standards. The gm5110/20 has many features that can be used to reduce electromagnetic interference (EMI). These include drive strength control and clock spectrum modulation. These features help to eliminate the costs associated with EMI reducing components and shielding. 4.13 OSD The gm5110/20 has a fully programmable, high-quality OSD controller. The graphics are divided into “cells” 12 by 18 pixels in size. The cells are stored in an on-chip static RAM (4096 words by 24 bits) and can be stored as 1-bit per pixel data, 2-bit per pixel data or 4-bit per pixel data. This permits a good compression ratio while allowing more than 16 colors in the image. Some general features of the gm5110/20 OSD controller include: OSD Position – The OSD menu can be positioned anywhere on the display region. The reference point is Horizontal and Vertical Display Background Start (DH_BKGND_START and DV_BKGND_START in Figure 18). OSD Stretch – The OSD image can be stretched horizontally and/or vertically by a factor of two, three, or four. Pixel and line replication is used to stretch the image. OSD Blending – Sixteen levels of blending are supported for the character-mapped and bitmapped images. One host register controls the blend levels for pixels with LUT values of 128 and greater, while another host register controls the blend levels for pixels with LUT values of 127 and lower. OSD color LUT value 0 is reserved for transparency and is unaffected by the blend attribute. June 2002 30 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.13.1 On-Chip OSD SRAM The on-chip static RAM (4096 words by 24 bits) stores the cell map and the cell definitions. In memory, the cell map is organized as an array of words, each defining the attributes of one visible character on the screen starting from upper left of the visible character array. These attributes specify which character to display, whether it is stored as 1, 2 or 4 bits per pixel, the foreground and background colors, blinking, etc. Registers CELLMAP_XSZ and CELLMAP_YSZ are used to define the visible area of the OSD image. For example, Figure 22 shows a cell map for which CELLMAP_XSZ =25 and CELLMAP_YSZ =10. Address 1: Cell Attributes for upper-left hand cell Address 25: Attributes for upper-right hand cell CELLMAP_XSZ Address26: Cell attributes for st 1 cell, 2nd row Brightness Contrast CELLMAP_YSZ Figure 22. OSD Cell Map Cell definitions are stored as bit map data. On-chip registers point to the start of 1-bit per pixel definitions, 2-bit per pixel definitions and 4-bit per pixel definitions respectively. 1, 2 and 4-bit per pixel cell definitions require 9, 18 and 36 words of the OSD RAM respectively. Note that the cell map and the cell definitions share the same on-chip RAM. Thus, the size of the cell map can be traded off against the number of different cell definitions. In particular, the size of the OSD image and the number of cell definitions must fit in OSD SRAM. That is, the following inequality must be satisfied. (Note, the ROUND operation rounds 3.5 to 4). (CELLMAP_XSZ+1) * CELLMAP_YSZ + 18 * ROUND(Number of 1-bit per pixel fonts / 2) + 18 * (Number of 2-bit per pixel fonts) + 36 * (Number of 4-bit per pixel fonts) <= 4096 For example, an OSD menu 360 pixels wide by 360 pixels high is 30 cells in width and 20 cells in height. Many of these cells would be the same (e.g. empty). In this case, the menu June 2002 31 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet could contain more than 32 1-bit per pixel cells, 100 2-bit per pixel cells, and 16 4-bit per pixel cells. Of course, different numbers of each type can also be used. 4.13.2 Color Look-up Table (LUT) Each pixel of a displayed cell is resolved to an 8-bit color code. This selected color code is then transformed to a 24-bit value using a 256 x 24-bit look up table. This LUT is stored in an on-chip RAM that is separate from the OSD RAM. Color index value 0x00 is reserved for transparent OSD pixels. 4.14 On-Chip Microcontroller (OCM) The gm5110/20 on-chip microcontroller (OCM) serves as the system microcontroller. It programs the gm5110/20 and manages other devices in the system such as the keypad, the back light and non-volatile RAM (NVRAM) using general-purpose input/output (GPIO) pins. The OCM can operate in two configurations, Standalone configuration and Full-Custom configuration, as illustrated in Figure 23. Factory Port Analog RGB Input Factory Port Analog RGB Input gm5110/20 Output to LCD Panel OCM DVI Input ROM NVRAM gm5110/20 OCM Output to LCD Panel DVI Input On-chip ROM: • Auto mode detection • Auto-configuration • Standard high-quality OSD menus • Factory test / calibration functions NVRAM Configuration settings in NVRAM: • OSD Colors, Logo and other configuration • Panel Parameters • Additional input modes • Code patches User settings in NVRAM: • Brightness/contrast settings, etc • On mode-by-mode basis PROM External ROM: • Contains firmware code and data for all firmware functions Figure 23A - Standalone Configuration Figure 23B - Full-Custom Configuration Figure 23. OCM Full-Custom and Standalone Configurations (No external ROM) June 2002 (Program and Data stored in external ROM) 32 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.14.1 Standalone Configuration Standalone configuration offers the most simple and inexpensive system solution for generic LCD monitors. In this configuration the OCM executes firmware stored internally in gm5110/20. This is illustrated in Figure 23A. The on-chip firmware provides all the standard functions required in a high-quality generic LCD monitor. This includes mode-detection, auto-configuration and a high-quality standard OSD menu system. No external ROM is required (which reduces BOM cost) and no firmware development effort is required (which reduces time-to-market). In Standalone configuration many customization parameters are stored in NVRAM. These include the LCD panel timing parameters (including TCON programming), the color scheme and logos used in the OSD menus, the functions provided by the OSD menus, and arbitrary firmware modifications. These customization parameters are described in the Standalone User’s Guide (B0108-SUG-01). Based on the customization parameters, G-Wizard (a GUIbased development tool used to program Genesis devices) produces the hex image file for NVRAM. G-Probe is then used to download the NVRAM image file into the NVRAM device. This is illustrated in Figure 24 below. Specify Configurable Parameters (See Standalone Users Guide) G-Wizard NVRAM Image File (.nvram_image. hex) G-Probe LCD Controller Board NVRAM gm5110/20 OCM Figure 24. June 2002 Programming OCM in Standalone Configuration 33 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.14.2 Full-Custom Configuration In full-custom configuration the OCM executes a firmware program running from external ROM. This is illustrated in Figure 23B. A parallel port with separate address and data busses is available for this purpose. This port connects directly to standard, commercially available ROM or programmable Flash ROM devices. Normally 64KB or 128KB of ROM is required. Both instructions and data are fetched from external ROM on a cycle-by-cycle basis. The speed of the accesses on the parallel port is determined by the gm5110/20 internal OCM_CLK. This in turn determines the speed of the external ROM device. For example, if a 14.3 MHz crystal is being used to produce TCLK, and the OCM_CLK is derived from TCLK, then a 45ns ROM can be used. To program gm5110/20 in full-custom configuration the content of the external ROM is generated using Genesis software development tools G-Wizard and OSD-Workbench. This is illustrated in Figure 25. G-Wizard is a GUI-based tool for capturing system information such as panel timing, support modes, system configuration, etc. OSD-Workbench is a GUI based tool for defining OSD menus and functionality. G-Wizard gm5110/20 Driver OSD Workbench gm5110/20 Driver Firmware source files (*.c *.h) Keil Compiler External ROM Image File (.hex) ROM Programmer LCD Controller Board ROM gm5110/20 OCM Figure 25. June 2002 Programming the OCM in Full-Custom Configuration 34 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Genesis recommends using Keil compiler (http://www.keil.com/) to compile the firmware source code into a hex file. This hex file is then downloaded into the external ROM using commercially available ROM programmers. For development purposes it may be useful to use a ROM emulator. For example, a PROMJET ROM emulator can be used (http://www.emutec.com/pjetmain.html). 4.14.3 General Purpose Inputs and Outputs (GPIO’s) The gm5110/20 has 21 general-purpose input/output (GPIO) pins. These are used by the OCM to communicate with other devices in the system such as keypad buttons, NVRAM, LEDs, audio DAC, etc. Each GPIO has independent direction control, open drain enable, for reading and writing. Note that the GPIO pins have alternate functionality as described in Table 17 below. Pin Name GPIO0/PWM0 GPIO1/PWM1 GPIO2/PWM2 GPIO3/TIMER1 GPIO4/UART_DI GPIO5/UARD_D0 GPIO6 GPIO7 GPIO8/IRQINn GPIO9 GPIO10 GPIO11/ROM_WEn GPIO12/NVRAM_SDA GPIO13/NVRAM_SCL GPIO14/DDC_SCL GPIO15/DDC_SDA GPIO16/HFSn GPIO17 GPIO18 GPIO19 GPIO20 GPIO21/IRQn GPIO22/HCLK GPO0 GPO1 GPO2 GPO3 GPO4 GPO5 GPO6 GPO7 Pin Number 40 41 42 43 44 45 46 47 39 48 49 50 51 52 6 7 205 1 208 207 206 4 204 119 120 121 122 123 124 125 126 Alternate function PWM0, PWM1 and PWM2 back light intensity controls, as described in section 4.17.2 below. Timer1 input of the OCM. OCM UART data in/out signals respectively. OCM external interrupt source (IRQINn). Write enable for external ROM if programmable FLASH device is used. Data and clock lines for master 2-wire serial interface to NVRAM when gm5110/20 is used in standalone configuration (section Figure 23). Clock and data lines for 2-wire serial interface connected to the Direct Data Channel (DDC) of the DVI input, for passing HDCP keys. Serial data line for 2-wire host interface. OCM interrupt output pin. Serial input clock for 2-wire host interface. General-purpose outputs. Table 17. gm5110/20 GPIOs and Alternate Functions 4.15 Bootstrap Configuration Pins During hardware reset, the external ROM address pins ROM_ADDR[15:0] are configured as inputs. On the negating edge of RESETn, the value on these pins is latched and stored. This value is readable by the on-chip microcontroller (or an external microcontroller via the host June 2002 35 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet interface). Install a 10K pull-up resistor to indicate a ‘1’, otherwise a ‘0’ is indicated because ROM_ADDR[15:0] have a 60KΩ internal pull-down resistor. Signal Name Pin Name Description HOST_ADDR(6:0) HOST_PROTOCOL HOST_PORT_EN OCM_START ROM_ADDR(6:0) ROM_ADDR7 ROM_ADDR8 ROM_ADDR9 USER_BITS(7:5) ROM_ADDR(12:10) OSC_SEL ROM_ADDR13 OCM_ROM_CNFG(1) ROM_ADDR14 If using 2-wire host protocol, these are the serial bus device address. Program this bit to 0 for 2-wire host interface operation. Program this bit to 0 for 2-wire host interface operation. Determines the operating condition of the OCM after HW reset: 0 = OCM remains in reset until enabled by register bit. 1 = OCM becomes active after OCM_CLK is stable. These settings are available for reading from a status register but are otherwise unused by the gm5110/20. Used to allow the OCM or external MCU access configuration settings. Selects reference clock source (refer to Figure 7): 0 = XTAL and TCLK pins are connected to a crystal oscillator. 1 = TCLK input is driven with a single-ended TTL/CMOS clock oscillator. Together with OCM_CONTROL register (0x22) bit 4, this bit selects internal/external ROM configuration. 0 = All 48K of ROM is internal. 1 = All 48K of ROM is in external ROM using ROM_ADDR15:0 address outputs if register 0x22 bit 4 is 0. If register 0x22 bit 4 is 1, 0-32K ROM is internal, and 32K~48K ROM is external using ROM_ADDR13:0 address outputs. Table 18. Bootstrap Signals 4.16 Host Interface A serial host interface is provided to allow an external device to peek and poke registers in the gm5110/20. This is done using a 2-wire serial protocol. Note that 2-wire host interface requires bootstrap settings as described in Table 18. The 2-wire host interface is suitable for connection to a factory interrogation port. This is illustrated in Figure 26. The factory test station connects to the gm5110/20 through the Direct Data Channel (DDC) of the DSUB15 or DVI connectors. For example, the PC can make gm5110/20 display test patterns (see section 4.5). A camera can be used to automate the calibration of the LCD panel. DDC Factory Test Station Device-Under-Test Camera Figure 26. Factory Calibration and Test Environment An arbitration mechanism ensures that register accesses from the OCM and the 2-wire host interface port are always serviced (time division multiplexing). June 2002 36 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 4.16.1 Host Interface Command Format Transactions on the 2-wire host protocol occurs in integer multiples of bytes (i.e. 8 bits or two nibbles respectively). These form an instruction byte, a device register address and/or one or more data bytes. This is described in Table 19. The first byte of each transfer indicates the type of operation to be performed by the gm5110/20. The table below lists the instruction codes and the type of transfer operation. The content of bytes that follow the instruction byte will vary depending on the instruction chosen. By utilizing these modes effectively, registers can be quickly configured. The two LSBs of the instruction code, denoted 'A9' and 'A8' in Table 19 below, are bits 9 and 8 of the internal register address respectively. Thus, they should be set to ‘00’ to select a starting register address of less than 256, ‘01’ to select an address in the range 256 to 511, and '10' to select an address in the range 512 to 767. These bits of the address increment in Address Increment transfers. The unused bits in the instruction byte, denoted by 'x', should be set to ‘1’. Table 19. Instruction Byte Map Bit 765432 1 0 0 0 0 1 x x A9 A8 0 0 1 0 x x A9 A8 Operation Mode Write Address Increment Write Address No Increment (for table loading) 1 0 0 1 x x A9 A8 1 0 1 0 x x A9 A8 Read Address Increment Read Address No Increment (for table reading) 0 0 1 1 x x A9 A8 0 1 0 0 x x A9 A8 1 0 0 0 x x A9 A8 1 0 1 1 x x A9 A8 1 1 0 0 x x A9 A8 0 0 0 0 x x A9 A8 0 1 0 1 x x A9 A8 0 1 1 0 x x A9 A8 0 1 1 1 x x A9 A8 1 1 0 1 x x A9 A8 1 1 1 0 x x A9 A8 1 1 1 1 x x A9 A8 Reserved Spare Description Allows the user to write a single or multiple bytes to a specified starting address location. A Macro operation will cause the internal address pointer to increment after each byte transmission. Termination of the transfer will cause the address pointer to increment to the next address location. Allows the user to read multiple bytes from a specified starting address location. A Macro operation will cause the internal address pointer to increment after each read byte. Termination of the transfer will cause the address pointer to increment to the next address location. No operation will be performed 4.16.2 2-wire Serial Protocol The 2-wire protocol consists of a serial clock HCLK (pin number 204) and bi-directional serial data line HFSn (pin number 205). The bus master drives HCLK and either the master or slave can drive the HFSn line (open drain) depending on whether a read or write operation is being performed. The gm5110/20 operates as a slave on the interface. The 2-wire protocol requires each device be addressable by a 7-bit identification number. The gm5110/20 is initialized on power-up to 2-wire mode by asserting bootstrap pins HOST_PROTOCOL=0 and the device identification number on HOST_ADDR(6:0) on the rising edge of RESETn (see Table 18). This provides flexibility in system configuration with multiple devices that can have the same address. June 2002 37 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet A 2-wire data transfer consists of a stream of serially transmitted bytes formatted as shown in the figure below. A transfer is initiated (START) by a high-to-low transition on HFSn while HCLK is held high. A transfer is terminated by a STOP (a low-to-high transition on HFSn while HCLK is held high) or by a START (to begin another transfer). The HFSn signal must be stable when HCLK is high, it may only change when HCLK is low (to avoid being misinterpreted as START or STOP). HCLK 1 2 3 4 5 6 7 8 9 1 2 8 9 HFSn A6 A5 A4 A3 A2 A1 A0 R/W ACK D7 D6 D0 ACK START STOP DATA BYTE ADDRESS BYTE Receiver acknowledges by holding SDA low Figure 27. 2-Wire Protocol Data Transfer Each transaction on the HFSn is in integer multiples of 8 bits (i.e. bytes). The number of bytes that can be transmitted per transfer is unrestricted. Each byte is transmitted with the most significant bit (MSB) first. After the eight data bits, the master releases the HFSn line and the receiver asserts the HFSn line low to acknowledge receipt of the data. The master device generates the HCLK pulse during the acknowledge cycle. The addressed receiver is obliged to acknowledge each byte that has been received. The Write Address Increment and the Write Address No Increment operations allow one or multiple registers to be programmed with only sending one start address. In Write Address Increment, the address pointer is automatically incremented after each byte has been sent and written. The transmission data stream for this mode is illustrated in Figure 28 below. The highlighted sections of the waveform represent moments when the transmitting device must release the HFSn line and wait for an acknowledgement from the gm5110/20 (the slave receiver). HCLK 1 2 HFSn 3 4 5 DEVICE ADDRESS 6 7 8 9 R/W ACK START 1 2 3 4 5 6 OPERATION CODE 7 8 A9 A8 9 ACK 1 2 3 4 5 6 REGISTER ADDRESS 7 8 9 ACK 1 2 9 DATA DATA Figure 28. ACK STOP Two MSBs of register address 2-Wire Write Operations (0x1x and 0x2x) The Read Address Increment (0x90) and Read Address No Increment (0xA0) operations are illustrated in Figure 29. The highlighted sections of the waveform represent moments when the transmitting device must release the HFSn line and waits for an acknowledgement from the master receiver. June 2002 38 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Note that on the last byte read, no acknowledgement is issued to terminate the transfer. HCLK HFSn DEVICEADDRESS R/W ACK OPERATIONCODE ACK REGISTERADDRESS ACK DEVICEADDRESS R/W ACK DATA DATA ACK DATA START START Figure 29. STOP 2-Wire Read Operation (0x9x and 0xAx) Please note that in all the above operations the operation code includes two address bits, as described in Table 19. 4.17 Miscellaneous Functions 4.17.1 Low Power State The gm5110/20 provides a low power state in which the clocks to selected parts of the chip may be disabled (see Table 21). 4.17.2 Pulse Width Modulation (PWM) Back Light Control Many of today’s LCD back light inverters require both a PWM input and variable DC voltage to minimize flickering (due to the interference between panel timing and inverter’s AC timing), and adjust brightness. Most LCD monitor manufactures currently use a microcontroller to provide these control signals. To minimize the burden on the external microcontroller, the gm5110/20 generates these signals directly. There are three pins available for controlling the LCD back light, PWM0 (GPIO0), PWM1 (GPIO1) and PWM2 (GPIO2). The duty cycle of these signals is programmable. They may be connected to an external RC integrator to generate a variable DC voltage for a LCD back light inverter. Panel HSYNC is used as the clock for a counter generating this output signal. June 2002 39 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 5. ELECTRICAL SPECIFICATIONS The following targeted specifications have been derived by simulation. 5.1 Preliminary DC Characteristics Table 20. Absolute Maximum Ratings PARAMETER (1,2) 3.3V Supply Voltages 2.5V Supply Voltages (1.2) Input Voltage (5V tolerant inputs) (1,2) Input Voltage (non 5V tolerant inputs) (1,2) Electrostatic Discharge Latch-up SYMBOL MIN VVDD_3.3 VVDD_2.5 VIN5Vtol VIN VESD -0.3 -0.3 -0.3 -0.3 Storage Temperature Operating Junction Temp. Thermal Resistance (Junction to Air) Natural Convection (3) gm5110 gm5120 (4) Thermal Resistance (Junction to Case) Convection gm5110 gm5120 Soldering Temperature (30 sec.) Vapor Phase Soldering (30 sec.) MAX UNITS 3.6 2.75 5.5 3.6 V V V V kV ±2.0 TA 0 ±100 70 TSTG -40 125 °C TJ 0 125 °C θJA_5110 θJA_5120 32.4 22.0 °C/W θJC_5110 θJC_5120 °C/W TSOL 13.9 10.1 220 TVAP 220 °C ILA Ambient Operating Temperature TYP mA °C NOTE (1): All voltages are measured with respect to GND NOTE (2): Absolute maximum voltage ranges are for transient voltage excursions. NOTE (3): Package thermal resistance is based on a PCB with one signal plane and two power planes. Package θJA is improved on a PCB with four or more layers NOTE (4): Based on the figures for the Operating Junction Temperature, θJC and Power Consumption in Table 21, the typical case temperature is calculated as TC = TJ - P x θJC. This equals 104 degrees Celsius for gm5110 and 106 degrees Celsius for gm5120. June 2002 40 C5110-DAT-01C °C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Table 21. DC Characteristics PARAMETER SYMBOL MIN TYP MAX UNITS POWER Power Consumption @ 96 MHz (gm5110) Power Consumption @ 135 MHz (gm5120) Power Consumption @ Low Power Mode (1) 3.3V Supply Voltages (AVDD and RVDD) 2.5V Supply Voltages (VDD and CVDD) Supply Current @ CLK = 96 MHz (gm5110) • 2.5V digital supply (2) (3) • 2.5V analog supply (4) • 3.3V digital supply (5) • 3.3V analog supply Supply Current @ CLK =135MHz (gm5120) • 2.5V digital supply (2) (3) • 2.5V analog supply (4) • 3.3V digital supply (5) • 3.3V analog supply Supply Current @ Low Power Mode* P5110 P5120 PLP VVDD_3.3 VVDD_2.5 I5110 3.15 2.35 1.5 1.8 0.15 3.3 2.5 400 3.45 2.65 W W W V V mA 360(6) (6) 40 50(6) 150(6) I5110_2.5_VDD I5110_2.5_AVDD I5110_3.3_VDD I5110_3.3_AVDD I5120 I5120_2.5_VDD I5120_2.5_AVDD I5120_3.3_VDD I5120_3.3_AVDD 500 ILP 50 mA 500(6) 50(6) 60(6) 150(6) mA INPUTS High Voltage Low Voltage Clock High Voltage Clock Low Voltage High Current (VIN = 5.0 V) Low Current (VIN = 0.8 V) Capacitance (VIN = 2.4 V) VIH VIL VIHC VILC IIH IIL CIN High Voltage (IOH = 7 mA) Low Voltage (IOL = -7 mA) Tri-State Leakage Current VOH VOL IOZ 2.0 GND 2.4 GND -25 -25 VDD 0.8 VDD 0.4 25 25 8 V V V V µA µA pF 2.4 GND -25 VDD 0.4 25 V V µA OUTPUTS NOTE (1): Low power figures result from setting the ADC, DVI, and clock power down bits so that only the micro-controller is running. NOTE (2): Includes pins CVDD_2.5, VDD1_ADC_2.5, VDD2_ADC_2.5, VDD_RX0_2.5, VDD_RX1_2.5 and VDD_RX2_2.5. NOTE (3): Includes only VDD_RXPLL_2.5. NOTE (4): Includes pins VDD_DPLL, VDD_SDDS, VDD_DDDS and RVDD. NOTE (5): Includes pins AVDD_RED, AVDD_GREEN, AVDD_BLUE, AVDD_IMB, AVDD_RX0, AVDD_RX1, AVDD_RX2, AVDD_RXC, AVDD_RPLL, AVDD_SDDS and AVDD_DDDS. NOTE (6): Maximum current figures are provided for the purposes of selecting an appropriate power supply circuit. 5.2 Preliminary AC Characteristics The following targeted specifications have been derived by simulation. All timing is measured to a 1.5V logic-switching threshold. The minimum and maximum operating conditions used were: TDIE = 0 to 125° C, Vdd = 2.35 to 2.65V, Process = best to worst, CL = 16pF for all outputs. June 2002 41 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet Table 22. Maximum Speed of Operation Clock Domain Main Input Clock (TCLK) DVI Differential Input Clock ADC Clock (ACLK) HCLK Host Interface Clock (6-wire protocol) Input Format Measurement Clock (IFM_CLK) Reference Clock (RCLK) On-Chip Microcontroller Clock (OCM_CLK) Display Clock (DCLK) Max Speed of Operation 24 MHz (14.3MHz recommended) 165MHz 162.5MHz 5 MHz 50MHz (14.3MHz recommended) 200MHz (200MHz recommended) 100 MHz 135 MHz Table 23. Display Timing and DCLK Adjustments DP_TIMING -> Propagation delay from DCLK to DA*/DB* Propagation delay from DCLK to DHS Propagation delay from DCLK to DVS Propagation delay from DCLK to DEN Tap 0 (default) Min Max (ns) (ns) 1.0 4.5 1.0 4.5 0.5 4.5 1.0 4.5 Tap 1 Min Max (ns) (ns) 0.5 3.5 0.5 3.5 0.0 3.5 0.5 3.5 Tap 2 Min Max (ns) (ns) -0.5 2.5 -0.5 2.5 -1.0 2.5 -0.5 2.5 Tap 3 Min Max (ns) (ns) -1.5 1.5 -1.5 1.5 -2.0 1.5 -1.5 1.5 Note: DCLK Clock Adjustments are the amount of additional delay that can be inserted in the DCLK path, in order to reduce the propagation delay between DCLK and its related signals. Table 24. 2-Wire Host Interface Port Timing Parameter SCL HIGH time SCL LOW time SDA to SCL Setup SDA from SCL Hold Propagation delay from SCL to SDA Symbol MIN TSHI TSLO TSDIS TSDIH TSDO3 1.25 1.25 30 20 10 TYP MAX Units 150 us us ns ns ns Note: The above table assumes OCM_CLK = R_CLK / 2 = 100 MHz (default) (ie 10ns / clock) June 2002 42 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 6. ORDERING INFORMATION Order Code Application Package Temperature Range gm5110 XGA 208-pin PQFP 0-70°C XGA 208-pin PQFP 0-70°C SXGA 208-pin PQFP 0-70°C SXGA 208-pin PQFP 0-70°C gm5110-H (1) gm5120 gm5120-H (1) Note (1): gm5110-H and gm5120-H versions will only be sold to HDCP licensed customers. June 2002 43 C5110-DAT-01C *** Genesis Microchip Confidential *** gm5110/20 Preliminary Data Sheet 7. MECHANICAL SPECIFICATIONS Figure 30. gm5110/gm5120 208-pin PQFP Mechanical Drawing HD D 208 157 E HE 156 1 105 52 53 e 104 c A1 A2 A b See Detail A y Seating Plane L L1 Detail A Symbol A A1 A2 b c D E e HD HE L L1 y 0 June 2002 Dimension in mm Min Nom 3.92 Max 4.07 0.25 3.15 3.23 0.18 0.28 0.23 0.13 27.90 27.90 3.30 28.00 28.10 28.00 28.10 0.50 BSC 30.95 31.20 31.45 30.95 31.20 31.45 0.65 0.80 0.95 1.60 REF 0.10 0 7 44 C5110-DAT-01C