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GRAPHICS S1D13705
S1D13705 Embedded Memory LCD Controller
X27A-C-001-04 2
GRAPHICS S1D13705
Memory Interface
CPU Interface
Display Support
Clock Source
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1.1 Scope
1.2 Overview Description
2 Features
2.1 Integrated Frame Buffer
2.2 CPU Interface
2.3 Display Support
2.4 Display Modes
2.5 Clock Source
2.6 Miscellaneous
2.7 Package
Page 12 Epson Research and Development
3 Typical System Implementation Diagrams
Figure 3-1: Typical System Diagram (SH-4 Bus)
Figure 3-2: Typical System Diagram (SH-3 Bus)
8-bit
SH-4
Figure 3-3: Typical System Diagram (M68K #1 Bus)
Figure 3-4: Typical System Diagram (M68K #2 Bus)
4-bit
MC68000
8-bit
Figure 3-5: Typical System Diagram (Generic #1 Bus)
Figure 3-6: Typical System Diagram (Generic #2 Bus - e.g. ISA Bus)
12-bit TFT
GENERIC #1
9-bit TFT
4 Functional Block Diagram
4.1 Functional Block Descriptions
4.1.1 Host Interface
4.1.2 Memory Controller
4.1.3 Sequence Controller
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5 Pins
5.1 Pinout Diagram
Figure 5-1: Pinout Diagram
Package type: 80 pin surface mount QFP14
S1D13705
5.2 Pin Description
Key:
5.2.1 Host Interface
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5.2.2 LCD Interface
5.2.3 Clock Input 5.2.4 Miscellaneous
5.2.5 Power Supply
5.3 Summary of Configuration Options
5.4 Host Bus Interface Pin Mapping
Table 5-1: Summary of Power On/Reset Options
Table 5-2: Host Bus Interface Pin Mapping
5.5 LCD Interface Pin Mapping
Table 5-3: LCD Interface Pin Mapping
6 D.C. Characteristics
Table 6-1: Absolute Maximum Ratings
Table 6-2: Recommended Operating Conditions for Core VDD = 3.3V 10%
Table 6-3: Input Specifications
Table 6-4: Output Specifications
7 A.C. Characteristics
7.1 Bus Interface Timing
7.1.1 SH-4 Interface Timing
Figure 7-1: SH-4 Timing
CKIO may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-1: SH-4 Timing
7.1.2 SH-3 Interface Timing
Figure 7-2: SH-3 Bus Timing
CKIO may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-2: SH-3 Bus Timing
7.1.3 Motorola MC68K #1 Interface Timing
Figure 7-3: MC68K #1 Bus Timing (MC68000)
CLK may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-3: MC68K #1 Bus Timing (MC68000)
7.1.4 Motorola MC68K #2 Interface Timing
Figure 7-4: MC68K #2 Timing (MC68030)
CLK may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-4: MC68K #2 Timing (MC68030)
7.1.5 Generic #1 Interface Timing
Figure 7-5: Generic #1 Timing
BCLK may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-5: Generic #1 Timing
7.1.6 Generic #2 Interface Timing
Figure 7-6: Generic #2 Timing
BCLK may be turned off (held low) between accesses - see Section 13.5, Turning Off
Table 7-6: Generic #2 Timing
7.2 Clock Input Requirements
Figure 7-7: Clock Input Requirements for CLKI
When CLKI is > 25MHz the Input Clock Divide bit (REG[02h] bit 4) must be set to 1.
Table 7-7: Clock Input Requirements for CLKI
Figure 7-8: Clock Input Requirements for BCLK Table 7-8: Clock Input Requirements for BCLK
7.3 Display Interface
7.3.1 Power On/Reset Timing
Figure 7-9: LCD Panel Power On/Reset Timing
Where TFPFRAME is the period of FPFRAME and TPCLK is the period of the pixel clock.
Table 7-9: LCD Panel Power On/Reset Timing
7.3.2 Power Down/Up Timing
Figure 7-10: Power Down/Up Timing Table 7-10: Power Down/Up Timing
7.3.3 Single Monochrome 4-Bit Panel Timing
Figure 7-11: Single Monochrome 4-Bit Panel Timing
Figure 7-12: Single Monochrome 4-Bit Panel A.C. Timing
4. t6min = [(REG[08h] bits 4-0) x 8 + 2]Ts 5. t7min = [(REG[08h] bits 4-0) x 8 + 11]Ts
Table 7-11: Single Monochrome 4-Bit Panel A.C. Timing
7.3.4 Single Monochrome 8-Bit Panel Timing
Figure 7-13: Single Monochrome 8-Bit Panel Timing
Figure 7-14: Single Monochrome 8-Bit Panel A.C. Timing
4. t6min = [(REG[08h] bits 4-0) x 8 + 4]Ts 5. t7min =[(REG[08h] bits 4-0) x 8 + 13]Ts
Table 7-12: Single Monochrome 8-Bit Panel A.C. Timing
7.3.5 Single Color 4-Bit Panel Timing
Figure 7-15: Single Color 4-Bit Panel Timing
Figure 7-16: Single Color 4-Bit Panel A.C. Timing
4. t6min = [(REG[08h] bits 4-0) x 8 + 1.5]Ts 5. t7min = [(REG[08h] bits 4-0) x 8 + 10]Ts
Table 7-13: Single Color 4-Bit Panel A.C. Timing
7.3.6 Single Color 8-Bit Panel Timing (Format 1)
Figure 7-17: Single Color 8-Bit Panel Timing (Format 1)
Figure 7-18: Single Color 8-Bit Panel A.C. Timing (Format 1)
Table 7-14: Single Color 8-Bit Panel A.C. Timing (Format 1)
7.3.7 Single Color 8-Bit Panel Timing (Format 2)
Figure 7-19: Single Color 8-Bit Panel Timing (Format 2)
Figure 7-20: Single Color 8-Bit Panel A.C. Timing (Format 2)
4. t6min = [(REG[08h] bits 4-0) x 8 + 1]Ts 5. t7min = [(REG[08h] bits 4-0) x 8 + 10]Ts
Table 7-15: Single Color 8-Bit Panel A.C. Timing (Format 2)
7.3.8 Dual Monochrome 8-Bit Panel Timing
Figure 7-21: Dual Monochrome 8-Bit Panel Timing
Figure 7-22: Dual Monochrome 8-Bit Panel A.C. Timing
Table 7-16: Dual Monochrome 8-Bit Panel A.C. Timing
7.3.9 Dual Color 8-Bit Panel Timing
Figure 7-23: Dual Color 8-Bit Panel Timing
Figure 7-24: Dual Color 8-Bit Panel A.C. Timing
Table 7-17: Dual Color 8-Bit Panel A.C. Timing
7.3.10 9/12-Bit TFT/D-TFD Panel Timing
Figure 7-25: 12-Bit TFT/D-TFD Panel Timing
Figure 7-26: TFT/D-TFD A.C. Timing
Note: DRDY is used to indicate the first pixel
Table 7-18: TFT/D-TFD A.C. Timing
8 Registers
8.1 Register Mapping
8.2 Register Descriptions
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This register must not be set to a value less than 03h.
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REG[04h] Horizontal Panel Size Register Address = 1FFE4h Read/Write
REG[05h] Vertical Panel Size Register (LSB) Address = 1FFE5h Read/Write
REG[06h] Vertical Panel Size Register (MSB) Address = 1FFE6h Read/Write
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For SwivelView mode the most significant bit (bit 16) is located in REG[10h].
REG[0Ch] Screen 1 Start Address Register (LSB) Address = 1FFECh Read/Write
REG[0Dh] Screen 1 Start Address Register (MSB) Address = 1FFEDh Read/Write
REG[0Eh] Screen 2 Start Address Register (LSB) Address = 1FFEEh Read/Write
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9 Frame Rate Calculation
The following formulae are used to calcu la te the display frame rate.
TFT/D-TFD and Passive Single-Panel modes
Passive Dual-Panel mode
Page 70 Epson Research and Development
10 Display Data Formats
Figure 10-1: 1/2/4/8 Bit-Per-Pixel Display Data Memory Organization
11 Look-Up Table Architecture
The following figures are intended to show the display data output path only.
When Video Data Invert is enabled the video data is inverted after the Look-Up Table.
11.1 Monochrome Modes
The green Look-Up Table (LUT) is used for all monochrome modes. 1 Bit-per-pixel Monochrome mode
4 Bit-per-pixel Monochrome Mode
Figure 11-3: 4 Bit-per-pixel Monochrome Mode Data Output Path
11.2 Color Modes
1 Bit-per-pixel Color Mode
Figure 11-4: 1 Bit-per-pixel Color Mode Data Output Path
2 Bit-per-pixel Color Mode
Figure 11-5: 2 Bit-per-pixel Color Mode Data Output Path
4 Bit-per-pixel Color Mode
Figure 11-6: 4 Bit-per-pixel Color Mode Data Output Path
8 Bit-per-pixel Color Mode
Figure 11-7: 8 Bit-per-pixel Color Mode Data Output Path
12 SwivelView
12.1 Default SwivelView Mode
12.1.1 How to Set Up Default SwivelView Mode
12.2 Alternate SwivelView Mode
12.2.1 How to Set Up Alternate SwivelView Mode
12.3 Comparison Between Default and Alternate SwivelView Modes
12.4 SwivelView Mode Limitations
Table 12-1: Default and Alternate SwivelView Mode Comparison
13 Power Save Modes
13.1 Software Power Save Mode
13.2 Hardware Power Save Mode
13.3 Power Save Mode Function Summary
13.4 Panel Power Up/Down Sequence
13.5 Turning Off BCLK Between Accesses
13.6 Clock Requirements
14 Mechanical Data
Figure 14-1: Mechanical Drawing QFP14
15 Sales and Technical Support
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2 Initialization
2.1 Display Buffer Location
2.2 Register Values
2.3 Frame Rate Calculation
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3 Memory Models
3.1 1 Bit-Per-Pixel (2 Colors/Gray Shades)
3.2 2 Bit-Per-Pixel (4 Colors/Gray Shades)
3.3 4 Bit-Per-Pixel (16 Colors/Gray Shades)
3.4 Eight Bit-Per-Pixel (256 Colors)
4 Look-Up Table (LUT)
4.1 Look-Up Table Registers
4.2 Look-Up Table Organization
4.2.1 Color Modes
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Table 4-4: Suggested LUT Values to Simulate VGA Default 256 Color Palette (Continued)
4.2.2 Gray Shade Modes
The following table shows the example values for 2 bit-per-pixel display mode.
Table 4-6: Suggested Values for 2 Bpp Gray Shade
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5 Advanced Techniques
5.1 Virtual Display
5.1.1 Registers
5.1.2 Examples
5.2 Panning and Scrolling
5.2.1 Registers
5.2.2 Examples
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5.3 Split Screen
5.3.1 Registers
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5.3.2 Examples
6 LCD Power Sequencing and Power Save Modes
6.1 LCD Power Sequencing
6.2 Registers
6.3 LCD Enable/Disable
7 Hardware Rotation
7.1 Introduction To Hardware Rotation
7.2 Default Portrait Mode
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7.3 Alternate Portrait Mode
7.4 Registers
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7.5 Limitations
7.6 Examples
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8 Identifying the S1D13705
9 Hardware Abstraction Layer (HAL)
9.1 Introduction
9.2 Contents of the HAL_STRUCT
9.3 Using the HAL library
9.4 API for 13705HAL
Table 9-1: HAL Functions (Continued)
9.4.1 Initialization
9.4.2 General HAL Support
void seGetHalVersion(const char ** pVersion, const char ** pStatus, const char **pStatusRevision)
int seSetBitsPerPixel(int BitsPerPixel)
int seGetBitsPerPixel(int * pBitsPerPixel)
int seGetBytesPerScanline(int * pBytes)
int seGetScreenSize(int * Width, int * Height)
int seDelay(int MilliSeconds)
int seGetLastUsableByte(long * plLastByte)
int seSetHighPerformance(BOOL OnOff)
9.4.3 Advanced HAL Functions
int seSetHWRotate(int Rotate)
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int seVirtInit(DWORD VirtX, DWORD * VirtY)
seVirtInit() must be been called before calli ng seVirtMove().
9.4.4 Register / Memory Access
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9.4.5 Power Save
9.4.6 Drawing
Functionality differs from the 135x HAL.
int seGetPixel(long x, long y, DWORD *pColor)
int seDrawLine(int x1, int y1, int x2, int y2, DWORD Color)
int seDrawRect(long x1, long y1, long x2, long y2, DWORD Color, BOOL SolidFill)
9.4.7 LUT Manipulation
int seGetLut(BYTE *pLUT, int Count)
int seSetLutEntry(int Index, BYTE *pEntry)
int seGetLutEntry(int index, BYTE *pEntry)
9.5 Porting LIBSE to a new target platform
9.5.1 Bu ilding the LIBSE library for SH3 target example
9.5.2 Building the HAL library for the target example
10 Sample Code
10.1 Sample code using the S1D13705 HAL API
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10.2 Sample code without using the S1D13705 HAL API
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10.3 Header Files
The header files included here are the required for the HAL sample to compile correctly.
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S1D13705 Register Summary X27A-R-001-03 Page 1 01/02/13
S1D13705 Register Summary X27A-R-001-03
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13705CFG Configuration Program
Document Number: X27A-B-001-03
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13705CFG
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13705CFG Configuration Tabs
General Tab
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Preferences Tab
Clocks Tab
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Panel Tab
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Panel Powe r Tab
Registers Tab
13705CFG Menus
Open...
Save
Save As...
Configure Multiple
Export
Enable Tooltips
ERD on the Web
About 13705CFG
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13705SHOW
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13705SPLT
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13705SPLT Example
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13705VIRT
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13705VIRT Example
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13705PLAY
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13705PLAY Example
Scripting
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13705BMP
This error message should never bee seen. Contact ERD.
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13705PWR
PC Platform
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Windows CE 2.x Display Drivers
Document Number: X27A-E-001-03
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WINDOWS CE 2.x DISPLAY DRIVERS
Example Driver Builds
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Installation for CEPC Environment
Configuration
Compile Switches
Mode File
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Wind River WindML v2.0 DISPLAY DRIVERS
Building a WindML v2.0 Display Driver
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Wind River UGL v1.2 Display Drivers
Document Number: X27A-E-003-02
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Wind River UGL v1.2 Display Drivers
Building a UGL v1.2 Display Driver
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Linux Console Driver
Building the Console Driver for Linux Kernel 2.2.x
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Building the Console Driver for Linux Kernel 2.4.x
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QNX Photon v2.0 Display Driver
Building the Photon v2.0 Display Driver
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S1D13XXX 32-Bit Windows Device Driver Installation Guide
Driver Requirements
Windows NT Version 4.0
Windows 2000
Windows 98/ME
Windows 95 OSR2
Previous Versions of Windows 95
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1.1 Features
2 Installation and Configuration
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3 LCD Interface Pin Mapping
Table 3-1: LCD Signal Connector (J5) Pinout
4 CPU/Bus Interface Connector Pinouts
Table 4-1: CPU/BUS Connector (H1) Pinout
Table 4-2: CPU/BUS Connector (H2) Pinout
5 Host Bus Interface Pin Mapping
Table 5-1: Host Bus Interface Pin Mapping
6 Technical Description
6.1 Embedded Memory Support
6.2 ISA Bus Support
6.2.1 Display Adapter Card Support
6.2.2 Expanded Memory Manager Support
6.3 Non-ISA Bus Support
6.4 Decoding Logic
6.5 Clock Input Support
6.6 LCD Panel Voltage Setting
6.7 Monochrome LCD Panel Support
6.8 Color Passive LCD Panel Support
6.9 Color TFT/D-TFD LCD Panel Support
6.10 Power Save Modes
6.11 Adjustable LCD Panel Negative Power Supply
6.12 Adjustable LCD Panel Positive Power Supply
6.13 CPU/Bus Interface Header Strips
7 Parts List
Page 20 Epson Research and Development
8 Schematic Diagrams
Figure 8-1: S1D13705B00C Schematic Diagram (1 of 4)
Epson Research and Development Page 21
Figure 8-2: S1D13705B00C Schematic Diagram (2 of 4)
Page 22 Epson Research and Development
Figure 8-3: S1D13705B00C Schematic Diagram (3 of 4)
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Figure 8-4: S1D13705B00C Schematic Diagram (4 of 4)
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2 Features
3 Installation and Configuration
3.1 Configuration DIP Switches
Table 3-1: Configuration DIP Switch Settings
3.2 Configuration Jumpers
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4 CPU Interface
4.1 CPU Interface Pin Mapping
Table 4-1: CPU Interface Pin Mapping
4.2 CPU Bus Connector Pin Mapping
Table 4-2: CPU Bus Connector (H1) Pinout
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Page 18 Epson Research and Development
5 LCD Interface Pin Mapping
1These pin mappings use signal names commonly used for each panel type, however
2LCDPWR on J5 can be inverted by setting JP6 to 1-2.
Table 5-1: LCD Signal Connector (J5)
Pin Name Connector Pin No.
6 Technical Description
6.1 PCI Bus Support
6.2 Direct Host Bus Interface Support
6.3 S1D13705 Embedded Memory
6.4 Adjustable LCD Panel Positive Power Supply (VDDH)
6.5 Adjustable LCD Panel Negative Power Supply (VLCD)
6.6 Passive/Active LCD Panel Support
6.7 Power Save Modes
6.8 Clock Options
7 Software
8 References
9 Parts List
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10 Schematics
Not Populated
Figure 10-1: S1D13705B00C Schematics (1 of 5)
Not Populated
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Figure 10-2: S1D13705B00C Schematics (2 of 5)
Page 28 Epson Research and Development
Figure 10-3: S1D13705B00C Schematics (3 of 5)
Epson Research and Development Page 29
Place close to PCIB pin 61 & 62Place close to PCIB pin 5 & 6 Place close to PCIA pin 2
S5U13705B00C Rev. 2.0 Evaluation Board User Manual S1D13705 Issue Date: 2002/09/16 X27A-G-014-02
Figure 10-4: S1D13705B00C Schematics (4 of 5)
Page 30 Epson Research and Development
Not Populated
Place jumper to disable FPGA
Figure 10-5: S1D13705B00C Schematics (5 of 5)
FPGA configuration EPROM
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12 Technical Support
12.1 EPSON LCD Controllers (S1D13705)
Windows CE 3.x Display Drivers
Document Number: X27A-E-006-01
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WINDOWS CE 3.x DISPLAY DRIVERS
Example Driver Builds
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Installation for CEPC Environment
Configuration
Compile Switches
Mode File
Resource Management Issues
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2 Interfacing to the TMPR3912
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3.3 Generic #2 Interface Mode
4 Direct Connection to the Toshiba TMPR3912
4.1 General Description
Figure 4-1: S1D13705 to TMPR3912 Direct Connection
See Section 3.1 on page 9 and Section 3.3 on page 11 for Generic #2 pin descriptions.
4.2 Memory Mapping and Aliasing
4.3 S1D13705 Configuration
5 Using the ITE IT8368E PC Card Buffer
5.1 Hardware Description
Figure 5-1: S1D13705 to TMPR3912 Connection Using an IT8368E
IT8368E
S1D13705
TMPR3912
5.2 IT8368E Configuration
5.3 Memory Mapping and Aliasing
5.4 S1D13705 Configuration
Table 5-2: S1D13705 Configuration Using the IT8368E
Table 5-1: TMPR3912 to PC Card Slots Address Mapping With and Without the IT8368E
6 Software
7.2 Toshiba MIPS TMPR3912 Processor 7.3 ITE IT8368E
http://www.toshiba.com/taec/nonflash/indexproducts.html
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1 S1D13705 Power Consumption
1.1 Conditions
Table 1-1: S1D13705 Total Power Consumption
2 Summary
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2 Interfacing to the MC68328
2.1 The MC68328 System Bus
2.2 Chip-Select Module
2.3 S1D13705 Host Bus Interface
2.3.1 Host Bus Pin Connection
2.3.2 Generic #1 Interface Mode
2.3.3 MC68K #1 Interface Mode
2.4 MC68328 To S1D13705 Interface
2.4.1 Hardware Description
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2.4.2 S1D13705 Hardware Configuration
2.4.3 MC68328 Chip Select Configuration
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3 Interfacing to the MC68EZ328
3.1 The MC68EZ328 System Bus
3.2 Chip-Select Module
3.3 S1D13705 Host Bus Interface
3.3.1 Host Bus Pin Connection
3.3.2 Generic #1 Interface Mode
3.4 MC683EZ28 To S1D13705 Interface
3.4.1 Hardware Description
3.4.2 S1D13705 Hardware Configuration
3.4.3 MC68EZ328 Chip Select Configuration
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4 Interfacing to the MC68VZ328
4.1 The MC68VZ328 System Bus
4.2 Chip-Select Module
4.3 S1D13705 Host Bus Interface
4.3.1 Host Bus Pin Connection
4.3.2 Generic #1 Interface Mode
4.3.3 MC68K #1 Interface Mode
4.4 MC68VZ328 To S1D13705 Interface
4.4.1 Hardware Description
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4.4.2 S1D13705 Hardware Configuration
4.4.3 MC68VZ328 Chip Select and Pin Configuration
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7.2 Motorola Dragonball Processors
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2 Interfacing to the NEC VR4102/VR4111
2.1 The NEC VR4102/VR4111 System Bus
2.1.2 LCD Memory Access Cycles
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4 VR4102/VR4111 to S1D13705 Interface
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4.3 NEC VR4102/VR4111 Configuration
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7.2 NEC Electronics Inc.
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2 Interfacing to the PC Card Bus
2.1 The PC Card System Bus
2.1.1 PC Card Overview
2.1.2 Memory Access Cycles
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4 PC Card to S1D13705 Interface
4.1 Hardware Connections
4.3 Register/Memory Mapping
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7.2 PC Card Standard
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2 Interfacing to the MPC821
2.1 The MPC8xx System Bus
2.2 MPC821 Bus Overview
2.2.1 Normal (Non-Burst) Bus Transactions
2.2.2 Burst Cycles
2.3 Memory Controller Module
2.3.1 General-Purpose Chip Select Module (GPCM)
2.3.2 User-Programmable Machine (UPM)
3.1 Host Bus Interface Modes
3.2 Generic #1 Host Bus Interface Mode
4 MPC821 to S1D13705 Interface
4.2 MPC821ADS Evaluation Board Hardware Connections
Table 4-1: List of Connections from MPC821ADS to S1D13705 (Continued)
4.3 S1D13705 Hardware Configuration
4.4 MPC821 Chip Select Configuration
4.5 Test Software
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7.1 EPSON LCD/CRT Controllers (S1D13705)
7.2 Motorola MPC821 Processor
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2 Interfacing to the MCF5307
2.1 The MCF5307 System Bus
2.1.2 Normal (Non-Burst) Bus Transactions
2.1.3 Burst Cycles
2.2 Chip-Select Module
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4 MCF5307 To S1D13705 Interface
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4.3 MCF5307 Chip Select Configuration
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7.2 Motorola MCF5307 Processor
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2 Interfacing to the PR31500/PR31700
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3.3 Generic #2 Interface Mode
4 Direct Connection to the Philips PR31500/PR31700
4.1 General Description
Figure 4-1: S1D13705 to PR31500/PR31700 Direct Connection
See Section 3.1 on page 9 and Section 3.3 on page 11 for Generic #2 pin descriptions.
4.2 Memory Mapping and Aliasing
4.3 S1D13705 Configuration and Pin Mapping
5 Using the ITE IT8368E PC Card Buffer
5.1 Hardware Description
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5.2 IT8368E Configuration
5.3 Memory Mapping and Aliasing
5.4 S1D13705 Configuration
6 Software
7.2 Philips MIPS PR31500/PR31700 Processor
7.3 ITE IT8368E
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Table of Contents
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1 Introduction
1.1 General Description
2 S1D13704/5 Bus Interface
2.1 Bus Interface Modes
2.2 Generic #2 Interface Mode
3 TMPR3912/22U and S1D13704/5 Interface
3.1 Hardware Connections
Figure 3-1: S1D13704 to TMPR3912/22U Interface
3.2 Memory Mapping and Aliasing
3.3 S1D13704/5 Configuration and Pin Mapping
4 CPU Module Description
4.1 Clock Signals 4.1.1 BUSCLK
4.1.2 CLKI
4.2 LCD Connectors 4.2.1 50-pin LCD Module Connector, J3
4.2.2 Standard Epson LCD Connector, J4
4.3 LCD Controller 4.3.1 S1D13704 vs. S1D13705
4.3.2 LCDPWR Polarity
4.3.3 S1D13704\75 Chip Select
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2 Interfacing to the NEC VR4181A
2.1 The NEC VR4181A System Bus
2.1.2 LCD Memory Access Signals
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4 VR4181A to S1D13705 Interface
Figure 4-1: Typical Implementation of VR4181A to S1D13705 Interface
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4.3 NEC VR4181A Configuration
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7.2 NEC Electronics Inc.
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2 Interfacing to an 8-bit Processor
2.1 The Generic 8-bit Processor System Bus
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4 8-Bit Processor to S1D13705 Interface
4.3 Register/Memory Mapping
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7.1 Epson LCD/CRT Controllers (S1D13705)