SSD1963 - HP InfoTech S.R.L.

SOLOMON SYSTECH
SEMICONDUCTOR TECHNICAL DATA
SSD1963
Advance Information
1215KB Embedded Display SRAM
LCD Display Controller
This document contains information on a new product. Specifications and information herein are subject to change
without notice.
http://www.solomon-systech.com
SSD1963
Rev 1.1
P 1/93
Jan 2010
Copyright © 2010 Solomon Systech Limited
Appendix: IC Revision history of SSD1963 Specification
Version
0.10
21-Nov-08
0.10
08-Dec-08
Change Items
Effective Date
24-Nov-08
1st Release
1.
2.
3.
4.
Changed the set_pll_mnk to set_pll_mn in section 7.2
Change register name in section 8
Removed ABC
Revised description for REG 0x00, 0x01, 0x0C, 0x0D, 0x0E, 0x10, 0x11,
0x21, 0x26, 0x28, 0x2A, 0x2B, 0x2C, 0x2E, 0x33, 0x34, 0x35, 0x36, 0x37,
0x3A, 0x3C, 0x3E, 0x44, 0x45, 0xA1, 0xB0, 0xB1, 0xB4, 0xB5, 0xB6, 0xB7,
0xB8, 0xB9, 0xBE, 0xBF, 0xD0, 0xD1, 0xD4, 0xE5.
5. Added max VIH in Table 12-1
6. Added Table 9-1
7. Added Table 11-1
8. Revised Figure 9-19
9. Revised Figure 14-2
10. Revised Figure 13-5
11. Corrected typo for Table 7-2
12. Revised test condition for 12 and 13
10-Dec-08
1.0
07-May-09
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
Changed status to Advance Information
Update min/max rating of VDDD and VDDPLL in Table 11-1
Added tape and reel drawing of 128-pin LQFP package in Section 15.3
Revised Section 13.2 5.
Added 12 bits for Table 7-1
Removed TTL interface
Revised section 7.1.5
Change the title of section 7.2
Revised command description in section 8
Removed the command 0x0C and 0x3A
Added figures in section 13.4
Revised figures in section 13.3
Revise Table 6-1
18-May-09
1.1
23-Dec-09
1.
2.
Update Table 7-1
Revised section 9.72
18-Jan-10
Solomon Systech
Jan 2010
P 2/93
Rev 1.1
SSD1963
CONTENTS
1
GENERAL DESCRIPTION ....................................................................................................... 8
2
FEATURES................................................................................................................................... 8
3
ORDERING INFORMATION ................................................................................................... 8
4
BLOCK DIAGRAM .................................................................................................................... 9
5
PIN ARRANGEMENT.............................................................................................................. 10
5.1
5.2
80 BALLS TFBGA................................................................................................................................................10
128 PINS LQFP ....................................................................................................................................................11
6
PIN DESCRIPTIONS ................................................................................................................ 13
7
FUNCTIONAL BLOCK DESCRIPTIONS ............................................................................ 16
7.1
MCU INTERFACE .................................................................................................................................................16
7.1.1
6800 Mode ..................................................................................................................................................16
7.1.2
8080 Mode ..................................................................................................................................................16
7.1.3
Register Pin Mapping .................................................................................................................................16
7.1.4
Pixel Data Format ......................................................................................................................................16
7.1.5
Tearing Effect Signal (TE) ..........................................................................................................................17
7.2
SYSTEM CLOCK GENERATION .............................................................................................................................18
7.3
FRAME BUFFER....................................................................................................................................................19
7.4
SYSTEM CLOCK AND RESET MANAGER ...............................................................................................................19
7.5
LCD CONTROLLER ..............................................................................................................................................20
7.5.1
Display Format ...........................................................................................................................................20
7.5.2
General Purpose Input/Output (GPIO) ......................................................................................................20
8
COMMAND TABLE ................................................................................................................. 21
9
COMMAND DESCRIPTIONS................................................................................................. 24
9.1
9.2
9.3
9.4
9.5
9.6
9.7
9.8
9.9
9.10
9.11
9.12
9.13
9.14
9.15
9.16
9.17
9.18
9.19
9.20
9.21
9.22
9.23
9.24
SSD1963
NO OPERATION ....................................................................................................................................................24
SOFTWARE RESET ................................................................................................................................................24
GET POWER MODE ..............................................................................................................................................24
GET ADDRESS MODE ...........................................................................................................................................25
GET DISPLAY MODE.............................................................................................................................................25
GET SIGNAL MODE ..............................................................................................................................................26
ENTER SLEEP MODE ............................................................................................................................................27
EXIT SLEEP MODE ...............................................................................................................................................27
ENTER PARTIAL MODE ........................................................................................................................................27
ENTER NORMAL MODE........................................................................................................................................27
EXIT INVERT MODE .............................................................................................................................................28
ENTER INVERT MODE ..........................................................................................................................................28
SET GAMMA CURVE ............................................................................................................................................29
SET DISPLAY OFF ................................................................................................................................................29
SET DISPLAY ON .................................................................................................................................................29
SET COLUMN ADDRESS .......................................................................................................................................30
SET PAGE ADDRESS .............................................................................................................................................30
WRITE MEMORY START ......................................................................................................................................31
READ MEMORY START ........................................................................................................................................32
SET PARTIAL AREA..............................................................................................................................................32
SET SCROLL AREA ...............................................................................................................................................34
SET TEAR OFF .....................................................................................................................................................36
SET TEAR ON.......................................................................................................................................................36
SET ADDRESS MODE ...........................................................................................................................................36
Rev 1.1
P 3/93
Jan 2010
Solomon Systech
9.25
9.26
9.27
9.28
9.29
9.30
9.31
9.32
9.33
9.34
9.35
9.36
9.37
9.38
9.39
9.40
9.41
9.42
9.43
9.44
9.45
9.46
9.47
9.48
9.49
9.50
9.51
9.52
9.53
9.54
9.55
9.56
9.57
9.58
9.59
9.60
9.61
9.62
9.63
9.64
9.65
9.66
9.67
9.68
9.69
9.70
9.71
9.72
9.73
9.74
9.75
SET SCROLL START .............................................................................................................................................39
EXIT IDLE MODE .................................................................................................................................................40
ENTER IDLE MODE ..............................................................................................................................................40
WRITE MEMORY CONTINUE ................................................................................................................................41
READ MEMORY CONTINUE ..................................................................................................................................42
SET TEAR SCANLINE ............................................................................................................................................43
GET TEAR SCANLINE ...........................................................................................................................................43
READ DDB ..........................................................................................................................................................44
SET LCD MODE...................................................................................................................................................44
GET LCD MODE ..................................................................................................................................................46
SET HORIZONTAL PERIOD ....................................................................................................................................47
GET HORIZONTAL PERIOD ...................................................................................................................................48
SET VERTICAL PERIOD ........................................................................................................................................49
GET VERTICAL PERIOD ........................................................................................................................................49
SET GPIO CONFIGURATION .................................................................................................................................50
GET GPIO CONFIGURATION ................................................................................................................................51
SET GPIO VALUE ................................................................................................................................................52
GET GPIO VALUE ...............................................................................................................................................52
SET POST PROC....................................................................................................................................................53
GET POST PROC ...................................................................................................................................................53
SET PWM CONFIGURATION ................................................................................................................................54
GET PWM CONFIGURATION ................................................................................................................................55
SET LCD GEN0....................................................................................................................................................57
GET LCD GEN0 ...................................................................................................................................................58
SET LCD GEN1....................................................................................................................................................59
GET LCD GEN1 ...................................................................................................................................................60
SET LCD GEN2....................................................................................................................................................61
GET LCD GEN2 ...................................................................................................................................................62
SET LCD GEN3....................................................................................................................................................63
GET LCD GEN3 ...................................................................................................................................................64
SET GPIO0 ROP..................................................................................................................................................65
GET GPIO0 ROP .................................................................................................................................................65
SET GPIO1 ROP..................................................................................................................................................66
GET GPIO1 ROP .................................................................................................................................................67
SET GPIO2 ROP..................................................................................................................................................67
GET GPIO2 ROP .................................................................................................................................................68
SET GPIO3 ROP..................................................................................................................................................69
GET GPIO3 ROP .................................................................................................................................................69
SET DBC CONFIGURATION ..................................................................................................................................70
GET DBC CONFIGURATION .................................................................................................................................71
SET DBC THRESHOLD .........................................................................................................................................72
GET DBC THRESHOLD ........................................................................................................................................73
SET PLL ..............................................................................................................................................................73
SET PLL MN .......................................................................................................................................................74
GET PLL MN ......................................................................................................................................................75
GET PLL STATUS ................................................................................................................................................75
SET DEEP SLEEP ..................................................................................................................................................75
SET LSHIFT FREQUENCY....................................................................................................................................76
GET LSHIFT FREQUENCY ...................................................................................................................................76
SET PIXEL DATA INTERFACE ...............................................................................................................................78
GET PIXEL DATA INTERFACE...............................................................................................................................78
10
MAXIMUM RATINGS.......................................................................................................... 79
11
RECOMMENDED OPERATING CONDITIONS ............................................................. 79
11.1
POWER-UP SEQUENCE ..........................................................................................................................................79
12
DC CHARACTERISTICS..................................................................................................... 80
13
AC CHARACTERISTICS..................................................................................................... 80
Solomon Systech
Jan 2010
P 4/93
Rev 1.1
SSD1963
13.1 CLOCK TIMING ....................................................................................................................................................80
13.2 MCU INTERFACE TIMING ....................................................................................................................................81
13.2.1 Parallel 6800-series Interface Timing ........................................................................................................81
13.2.2 Parallel 8080-series Interface Timing ........................................................................................................83
13.3 PARALLEL LCD INTERFACE TIMING....................................................................................................................85
13.4 SERIAL RGB INTERFACE TIMING ........................................................................................................................86
14
APPLICATION EXAMPLE.................................................................................................. 88
15
PACKAGE INFORMATION................................................................................................ 90
15.1
15.2
15.3
SSD1963
PACKAGE MECHANICAL DRAWING FOR 80 BALLS TFBGA .................................................................................90
PACKAGE MECHANICAL DRAWING FOR 128 PINS LQFP......................................................................................91
TAPE & REEL DRAWING FOR 128 PINS LQFP ......................................................................................................92
Rev 1.1
P 5/93
Jan 2010
Solomon Systech
TABLES
TABLE 3-1: ORDERING INFORMATION ...................................................................................................................................8
TABLE 5-1: TFBGA PIN ASSIGNMENT TABLE .....................................................................................................................10
TABLE 5-2 : LQFP PIN ASSIGNMENT TABLE .......................................................................................................................12
TABLE 6-1: MCU INTERFACE PIN MAPPING ........................................................................................................................13
TABLE 6-2: LCD INTERFACE PIN MAPPING .........................................................................................................................14
TABLE 6-3: CONTROL SIGNAL PIN MAPPING .......................................................................................................................14
TABLE 6-4: POWER PIN MAPPING ........................................................................................................................................14
TABLE 6-5 : LCD INTERFACE PIN MAPPING ........................................................................................................................15
TABLE 7-1: PIXEL DATA FORMAT .......................................................................................................................................17
TABLE 7-2: FRAME BUFFER SETTINGS REGARDING TO SET_ADDRESS_MODE COMMAND ....................................................19
TABLE 9-1 ENTER IDLE MODE MEMORY CONTENT VS DISPLAY COLOR ...............................................................................41
TABLE 10-1: MAXIMUM RATINGS (VOLTAGE REFERENCED TO VSS) ...................................................................................79
TABLE 11-1: RECOMMENDED OPERATING CONDITION ........................................................................................................79
TABLE 12-1 : DC CHARACTERISTICS ...................................................................................................................................80
TABLE 13-1 : CLOCK INPUT REQUIREMENTS FOR CLK .......................................................................................................80
TABLE 13-2 : CLOCK INPUT REQUIREMENTS FOR CRYSTAL OSCILLATOR XTAL .................................................................80
TABLE 13-3: PARALLEL 6800-SERIES INTERFACE TIMING CHARACTERISTICS (USE CS# AS CLOCK)...................................81
TABLE 13-4: PARALLEL 6800-SERIES INTERFACE TIMING CHARACTERISTICS (USE E AS CLOCK) .......................................82
TABLE 13-5: PARALLEL 8080-SERIES INTERFACE TIMING CHARACTERISTICS .....................................................................83
Solomon Systech
Jan 2010
P 6/93
Rev 1.1
SSD1963
FIGURES
FIGURE 4-1: SSD1963 BLOCK DIAGRAM ..............................................................................................................................9
FIGURE 5-1: PINOUT DIAGRAM –TFBGA (TOPVIEW).........................................................................................................10
FIGURE 5-2 : PINOUT DIAGRAM – LQFP (TOPVIEW) ...........................................................................................................11
FIGURE 7-1: RELATIONSHIP BETWEEN TEARING EFFECT SIGNAL AND MCU MEMORY WRITING........................................18
FIGURE 7-2: CLOCK CONTROL DIAGRAM ............................................................................................................................19
FIGURE 7-3: STATE DIAGRAM OF SSD1963.........................................................................................................................20
FIGURE 9-1: EXIT INVERT MODE EXAMPLE ..........................................................................................................................28
FIGURE 9-2: ENTER INVERT MODE EXAMPLE .......................................................................................................................29
FIGURE 9-3: SET COLUMN ADDRESS EXAMPLE ...................................................................................................................30
FIGURE 9-4: SET PAGE ADDRESS EXAMPLE .........................................................................................................................31
FIGURE 9-5: SET PARTIAL AREA WITH SET ADDRESS MODE 0X36 A[4] = 0........................................................................33
FIGURE 9-6: SET PARTIAL AREA WITH SET ADDRESS MODE 0X36 A[4] = 1........................................................................33
FIGURE 9-7: SET PARTIAL AREA WITH SET ADDRESS MODE 0X36 A[4] = 0........................................................................33
FIGURE 9-8: SET PARTIAL AREA WITH SET ADDRESS MODE 0X36 A[4] = 1........................................................................33
FIGURE 9-9: SET SCROLL AREA WITH SET ADDRESS MODE 0X36 A[4] = 0.........................................................................35
FIGURE 9-10: SET SCROLL AREA WITH SET ADDRESS MODE 0X36 A[4] = 1 .......................................................................35
FIGURE 9-11: A[7] PAGE ADDRESS ORDER .........................................................................................................................37
FIGURE 9-12: A[6] COLUMN ADDRESS ORDER ....................................................................................................................37
FIGURE 9-13: A[5] PAGE / COLUMN ADDRESS ORDER ........................................................................................................37
FIGURE 9-14: A[3] RGB ORDER..........................................................................................................................................38
FIGURE 9-15: A[1] FLIP HORIZONTAL .................................................................................................................................38
FIGURE 9-16: A[0] FLIP VERTICAL ......................................................................................................................................39
FIGURE 9-17: SET SCROLL START WITH SET ADDRESS MODE, 0X36 A[4] = 0.....................................................................39
FIGURE 9-18: SET SCROLL START WITH SET ADDRESS MODE, 0X36 A[4] = 1.....................................................................40
FIGURE 9-19: PWM SIGNAL ................................................................................................................................................54
FIGURE 11-1: POWER-UP SEQUENCE ...................................................................................................................................79
FIGURE 13-1: PARALLEL 6800-SERIES INTERFACE TIMING DIAGRAM (USE CS# AS CLOCK)...............................................81
FIGURE 13-2: PARALLEL 6800-SERIES INTERFACE TIMING DIAGRAM (USE E AS CLOCK) ...................................................82
FIGURE 13-3: PARALLEL 8080-SERIES INTERFACE TIMING DIAGRAM (WRITE CYCLE) .......................................................83
FIGURE 13-4: PARALLEL 8080-SERIES INTERFACE TIMING DIAGRAM (READ CYCLE).........................................................84
FIGURE 13-5: GENERIC TFT PANEL TIMING ........................................................................................................................85
FIGURE 13-6: SERIAL RGB INTERFACE TIMING (WITHOUT DUMMY MODE).........................................................................86
FIGURE 13-7: SERIAL RGB INTERFACE TIMING (WITH DUMMY MODE) ...............................................................................87
FIGURE 14-1 : APPLICATION CIRCUIT FOR SSD1963 (WITH DIRECT CLOCK INPUT).............................................................88
FIGURE 14-2 : APPLICATION CIRCUIT FOR SSD1963 (WITH CRYSTAL OSCILLATOR INPUT) .................................................89
SSD1963
Rev 1.1
P 7/93
Jan 2010
Solomon Systech
1
GENERAL DESCRIPTION
SSD1963 is a display controller of 1215K byte frame buffer to support up to 864 x 480 x 24bit graphics
content. It also equips parallel MCU interfaces in different bus width to receive graphics data and command
from MCU. Its display interface supports common RAM-less LCD driver of color depth up to 24 bit-perpixel.
2
FEATURES
•
•
•
•
•
•
•
•
3
Display feature
− Built-in 1215K bytes frame buffer. Support up to 864 x 480 at 24bpp display
− Support TFT 18/24-bit generic RGB interface panel
− Support 8-bit serial RGB interface
− Hardware rotation of 0, 90, 180, 270 degree
− Hardware display mirroring
− Hardware windowing
− Programmable brightness, contrast and saturation control
− Dynamic Backlight Control (DBC) via PWM signal
MCU connectivity
− 8/9/16/18/24-bit MCU interface
− Tearing effect signal
I/O Connectivity
− 4 GPIO pins
Built-in clock generator
Deep sleep mode for power saving
Core supply power (VDDPLL and VDDD): 1.2V±0.1V
I/O supply power(VDDIO): 1.65V to 3.6V
LCD interface supply power (VDDLCD): 1.65V to 3.6V
ORDERING INFORMATION
Table 3-1: Ordering Information
Ordering Part Number
Solomon Systech
Package Form
SSD1963G41
TFBGA-80 (Tray)
SSD1963QL9
LQFP-128 (Tray)
SSD1963QL9R
LQFP-128 (Tape & Reel)
Jan 2010
P 8/93
Rev 1.1
SSD1963
4
BLOCK DIAGRAM
Figure 4-1: SSD1963 Block Diagram
`
SSD1963
Rev 1.1
P 9/93
Jan 2010
Solomon Systech
5
PIN ARRANGEMENT
5.1
80 balls TFBGA
Figure 5-1: Pinout Diagram –TFBGA (Topview)
Table 5-1: TFBGA Pin Assignment Table
Pin #
A1
A2
A3
A4
A5
A6
A7
A8
A9
B1
B2
B3
B4
B5
B6
B7
B8
B9
Signal Name
LDATA16
LDATA15
GAMAS1
TE
LSHIFT
GPIO2
GPIO1
GPIO0
VDDLCD
LDATA14
LDATA13
GAMAS0
PWM
LLINE
GPIO3
LDATA20
XTAL_OUT
Solomon Systech
Pin #
C1
C2
C3
C4
C5
C6
C7
C8
C9
D1
D2
D3
D4
D5
D6
D7
D8
D9
Signal Name
VDDLCD
LDATA12
LDATA11
LDATA10
LDATA9
LDEN
LDATA17
LDATA21
XTAL_IN
VSS
LDATA8
LDATA7
LDATA6
LDATA5
LFRAME
LDATA23
LDATA22
VSSPLL
Pin #
E1
E2
E3
E4
E5
E6
E7
E8
E9
F1
F2
F3
F4
F5
F6
F7
F8
F9
Signal Name
LDATA4
LDATA3
LDATA2
LDATA1
VSS
VDDD
R/W# (WR#)
D[4]
VDDPLL
LDATA18
LDATA19
LDATA0
D[19]
VSS
VDDD
E(RD#)
D[3]
CLK
Pin #
G1
G2
G3
G4
G5
G6
G7
G8
G9
H1
H2
H3
H4
H5
H6
H7
H8
H9
Jan 2010
Signal Name
D[22]
D[23]
D[18]
D[13]
D[10]
D[7]
D/C#
D[2]
D[1]
D[21]
D[17]
D[15]
D[12]
D[9]
D[6]
CS#
CONF
D[0]
P 10/93
Pin #
J1
J2
J3
J4
J5
J6
J7
J8
J9
Rev 1.1
Signal Name
D[20]
D[16]
D[14]
D[11]
D[8]
D[5]
RESET#
VSS
VDDIO
SSD1963
5.2
128 pins LQFP
D17
D16
VDDIO
97
98
99
100
VDDIO
VSS
101
D15
D14
VDDD
102
103
104
D13
105
D12
106
D11
107
VSS
VDDIO
108
109
VDDD
110
111
D10
D8
D7
D9
112
113
114
D6
115
D5
116
VSS
VDDD
VDDIO
117
118
119
120
R/W#(WR#)
E(RD#)
121
CS#
D/C#
122
123
124
VDDIO
VSS
125
CONF
VDDD
126
127
128
RESET#
Figure 5-2 : Pinout Diagram – LQFP (Topview)
VDDD
1
96
VSS
VSS
2
95
VDDIO
VSS
3
94
VSS
VDDIO
4
93
VDDD
VSS
5
92
D20
VDDD
6
91
D21
D0
7
90
D22
D1
8
89
D23
D2
9
88
D18
D3
10
87
D19
D4
11
86
LDATA18
VDDIO
12
85
LDATA19
VSS
13
84
VDDLCD
VDDD
14
83
VSS
CLK
15
82
VDDD
81
LDATA0
VDDIO
16
VSS
17
VDDPLL
18
SSD1963
80
LDATA1
79
LDATA2
VSSPLL
19
78
LDATA3
VSS
20
77
LDATA4
VDDD
21
76
LDATA5
XTAL_IN
22
75
VDDLCD
VSS
23
74
VSS
XTAL_OUT
24
73
VDDD
VDDD
25
72
LDATA6
VSS
26
71
LDATA7
VDDLCD
27
70
LDATA8
LDATA23
28
69
LDATA9
P 11/93
Jan 2010
56
57
58
59
60
61
62
63
64
VSS
VDDLCD
LDATA16
LDATA15
LDATA14
LDATA13
LDATA12
VDDD
54
VDDLCD
55
53
GAMAS1
VSS
52
GAMAS0
VDDD
51
49
LDEN
50
48
TE
47
VDDLCD
PWM
46
VSS
45
VDDD
LSHIFT
44
LLINE
43
LFRAME
41
42
VDDLCD
40
VDDD
Rev 1.1
VSS
39
GPIO3
LDATA17
VDDLCD
VSS
SSD1963
38
VSS
37
VDDLCD
65
GPIO2
66
32
36
31
VDDD
GPIO1
LDATA20
35
LDATA10
LDATA11
GPIO0
68
67
34
29
30
33
LDATA22
LDATA21
Solomon Systech
Table 5-2 : LQFP Pin Assignment Table
Pin #
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
Signal Name
VDDD
VSS
VSS
VDDIO
VSS
VDDD
D0
D1
D2
D3
D4
VDDIO
VSS
VDDD
CLK
VDDIO
VSS
VDDPLL
VSSPLL
VSS
VDDD
XTAL_IN
VSS
XTAL_OUT
VDDD
VSS
VDDLCD
LDATA23
LDATA22
LDATA21
LDATA20
VDDD
Solomon Systech
Pin #
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
51
52
53
54
55
56
57
58
59
60
61
62
63
64
Signal Name
VSS
VDDLCD
LDATA17
GPIO0
GPIO1
GPIO2
GPIO3
VDDD
VSS
VDDLCD
LFRAME
LLINE
LSHIFT
VDDD
VSS
VDDLCD
LDEN
TE
PWM
GAMAS0
GAMAS1
VDDLCD
VSS
VDDD
VSS
VDDLCD
LDATA16
LDATA15
LDATA14
LDATA13
LDATA12
VDDD
Pin #
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
Signal Name
VSS
VDDLCD
LDATA11
LDATA10
LDATA9
LDATA8
LDATA7
LDATA6
VDDD
VSS
VDDLCD
LDATA5
LDATA4
LDATA3
LDATA2
LDATA1
LDATA0
VDDD
VSS
VDDLCD
LDATA19
LDATA18
D19
D18
D23
D22
D21
D20
VDDD
VSS
VDDIO
VSS
Jan 2010
Pin #
97
98
99
100
101
102
103
104
105
106
107
108
109
110
111
112
113
114
115
116
117
118
119
120
121
122
123
124
125
126
127
128
P 12/93
Signal Name
VDDIO
D17
D16
VDDIO
VSS
VDDD
D15
D14
D13
D12
D11
VDDIO
VSS
VDDD
D10
D9
D8
D7
D6
D5
VDDIO
VSS
VDDD
R/W#(WR#)
E(RD#)
D/C#
CS#
VDDIO
VSS
VDDD
RESET#
CONF
Rev 1.1
SSD1963
6
PIN DESCRIPTIONS
Key:
I = Input
O =Output
IO = Bi-directional (input/output)
P = Power pin
Hi-Z = High impedance
Table 6-1: MCU Interface Pin Mapping
Pin Name
Reference
Type Voltage
Level
TFBGA
Pin #
LQFP
Pin #
CLK
I
VDDIO
F9
15
XTAL_IN
I
-
C9
22
XTAL_OUT
O
-
B9
24
CS#
D/C#
I
I
VDDIO
VDDIO
H7
G7
123
122
E(RD#)
I
VDDIO
F7
121
R/W#(WR#)
I
VDDIO
E7
120
D[23:0]
IO
VDDIO
E8, F4, F8,
G1, G2, G3,
G4, G5, G6,
G8, G9, H1,
H2, H3, H4,
H5, H6, H9,
J1, J2,J3, J4,
J5, J6
TE
O
VDDLCD
A5
SSD1963
Rev 1.1
P 13/93
Jan 2010
Description
TTL clock input. This pin should be tied to VSS if
TTL clock input is not used
Crystal oscillator input. This pin should be tied to
VSS if not used
Crystal oscillator output. This pin should be floating
if not used
Chip select
Data/Command select
6800 mode: E (enable signal)
8080 mode: RD# (read strobe signal)
6800 mode: R/W#
0: Write cycle
1: Read cycle
8080 mode: WR# (write strobe signal)
7, 8, 9, 10,
11, 87, 88,
89, 90, 91,
92, 98, 99,
Data bus. Pins not used should be floating
103, 104,
105, 106,
107, 111,
112, 113,
114, 115, 116
50
Tearing effect
Solomon Systech
Table 6-2: LCD Interface Pin Mapping
Pin Name
LFRAME
LLINE
LSHIFT
LDEN
Reference
Type Voltage
Level
O
VDDLCD
O
VDDLCD
O
VDDLCD
O
VDDLCD
TFBGA
Pin #
LQFP
Pin #
D6
B6
A6
C6
A2, A3, B2,
B3, B8, C2,
C3, C4, C5,
C7, C8, D2,
D3, D4, D5,
D7, D8, E1,
E2, E3, E4,
F1, F2, F3
43
44
45
49
28, 29, 30,
31, 35, 59,
60, 61, 62,
63, 67, 68,
69, 70, 71,
72, 76, 77,
78, 79, 80,
81, 85, 86
LDATA[23:0]
O
VDDLCD
GPIO[3:0]
IO
VDDLCD
A7, A8, A9,
B7
GAMAS [1:0]
PWM
O
O
VDDLCD
VDDLCD
A4, B4
B5
Description
Vertical sync (Frame pulse)
Horizontal sync (Line pulse)
Pixel clock (Pixel shift signal)
Data valid
RGB data
These pins can be configured for display
36, 37, 38, 39 miscellaneous signals or as general purpose I/O.
Default as input
52, 53
Gamma selection for panel
51
PWM output for backlight driver
Table 6-3: Control Signal Pin Mapping
Pin Name
RESET#
CONF
Reference
Type Voltage
Level
I
VDDIO
I
VDDIO
TFBGA
Pin #
LQFP
Pin #
J7
127
H8
128
Description
Master synchronize reset
MCU interface configuration
0: 6800 Interface
1: 8080 Interface
Table 6-4: Power Pin Mapping
Pin Name
Type
VDDD
P
VDDLCD
P
VDDPLL
P
VDDIO
P
VSS
P
VSSPLL
P
Solomon Systech
TFBGA
Pin #
LQFP
Description
Pin #
1, 6, 14, 21, 25, 32,
E6, F6
40, 46, 56, 64, 73, 82, Power supply for internal digital circuit
93, 102, 110, 119, 126
27, 34, 42, 48, 54, 58,
B1, C1
Power supply for LCD interface related pads
66, 75, 84
Power supply for internal analog circuit and
E9
18
analog I/O pads
4, 12, 16,
J9
95, 97, 100, 108, 117, Power supply for digital I/O pads
124
2, 3, 5, 13, 17, 20, 23,
26, 33, 41, 47, 55, 57,
D1, E5, F5, J8
Ground for internal digital circuit
65, 74, 83, 94, 96,
101, 109, 118, 125
Ground for internal analog circuit and analog I/O
D9
19
pads
Jan 2010
P 14/93
Rev 1.1
SSD1963
Table 6-5 : LCD Interface Pin Mapping
Pin Names
LFRAME
LLINE
LSHIFT
LDEN
LDATA23
LDATA22
LDATA21
LDATA20
LDATA19
LDATA18
LDATA17
LDATA16
LDATA15
LDATA14
LDATA13
LDATA12
LDATA11
LDATA10
LDATA9
LDATA8
LDATA7
LDATA6
LDATA5
LDATA4
LDATA3
LDATA2
LDATA1
LDATA0
24-bit
R7
R6
R5
R4
R3
R2
R1
R0
G7
G6
G5
G4
G3
G2
G1
G0
B7
B6
B5
B4
B3
B2
B1
B0
18-bit
FRAME
LINE
SHIFT
DEN
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
R5
R4
R3
R2
R1
R0
G5
G4
G3
G2
G1
G0
B5
B4
B3
B2
B1
B0
8-bit serial
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
Drive 0
D7
D6
D5
D4
D3
D2
D1
D0
Note
(1) These pin mappings use signal names commonly used for each panel type, however signal names
may differ between panel manufacturers.
SSD1963
Rev 1.1
P 15/93
Jan 2010
Solomon Systech
7
FUNCTIONAL BLOCK DESCRIPTIONS
7.1
MCU Interface
The MCU interface connects the MCU and SSD1963 graphics controller. The MCU interface can be
configured as 6800 mode and 8080 mode by the CONF pin. By pulling the CONF pin to VSSIO, the MCU
interface will be configured as 6800 mode interface. If the CONF pin is connected to VDDIO, the MCU
interface will be configure in 8080 mode.
7.1.1
6800 Mode
The 6800 mode MCU interface consist of CS#, D/C#, E, R/W#, D[23:0], and TE signals (Please refer to
Table 6-1 for pin multiplexed with 8080 mode). This interface supports both fixed E and clock E scheme to
define a read/write cycle. If the E signal is kept high and used as enable signal, the CS# signal acts as a bus
clock, the data or command will be latched into the system at the rising edge of CS#. If the user wants to use
the E pin as the clock pin, the CS# pin then need to be fixed to logic 0 to select the chip. Then the falling
edge of the E signal will latch the data or command. For details, please refer to the timing diagram in chapter
13.2.1.
7.1.2
8080 Mode
The 8080 mode MCU interface consist of CS#, D/C#, RD#, WR#, D[23:0] and TE signals (Please refer to
Table 6-1 for pin multiplexed with 6800 mode). This interface use WR# to define a write cycle and RD# for
read cycle. If the WR# goes low when the CS# signal is low, the data or command will be latched into the
system at the rising edge of WR#. Similarly, the read cycle will start when RD# goes low and end at the
rising edge of RD#. The detailed timing will show in the chapter 13.2.2.
7.1.3
Register Pin Mapping
When user access the registers via the parallel MCU interface, only D[7:0] will be used regardless the width
of the pixel data is. Therefore, D[23:8] will only be used to address the display data only. This provided the
possibility that the pixel data format as shown in Table 7-1 can be configured by command 0xF0.
7.1.4
Pixel Data Format
Both 6800 and 8080 support 8-bit, 9-bit, 16-bit, 18-bit and 24-bit data bus. Depending on the width of the
data bus, the display data are packed into the data bus in different ways.
Solomon Systech
Jan 2010
P 16/93
Rev 1.1
SSD1963
Table 7-1: Pixel Data Format
Interface
Cycle D[23] D[22] D[21] D[20] D[19] D[18] D[17] D[16] D[15] D[14] D[13] D[12] D[11] D[10] D[9] D[8] D[7] D[6] D[5] D[4] D[3] D[2] D[1] D[0]
R0
G7
G6
G5
G4
G3
G2
G1
G0
B7
B6
B5
B4
B3
B2
B1
B0
R5
R4
R3
R2
R1
R0
G5
G4
G3
G2
G1
G0
B5
B4
B3
B2
B1
B0
st
R5
R4
R3
R2
R1
G5
G4
G3
G2
G1
G0
B5
B4
B3
B2
B1
st
R7
R6
R5
R4
R3
R2
R1
R0
G7
G6
G5
G4
G3
G2
G1
G0
nd
B7
B6
B5
B4
B3
B2
B1
B0
R7
R6
R5
R4
R3
R2
R1
R0
rd
G7
G6
G5
G4
G3
G2
G1
G0
B7
B6
B5
B4
B3
B2
B1
B0
1s t
R7
R6
R5
R4
R3
R2
R1
R0
G7
G6
G5
G4
2nd
G3
G2
G1
1
18 bits
1
16 bits (565 format)
1
1
16 bits
2
3
12 bits
9 bits
3
7.1.5
R6
R5
R4
R3
R2
G0
B7
B6
B5
B4
B3
B2
B1
B0
R5
R4
R3
R2
R1
R0
G5
G4
G3
nd
G2
G1
G0
B5
B4
B3
B2
B1
B0
st
R7
R6
R5
R4
R3
R2
R1
R0
nd
G7
G6
G5
G4
G3
G2
G1
G0
rd
B7
B6
B5
B4
B3
B2
B1
B0
1
2
R7
st
st
1
2
8 bits
st
R1
24 bits
Tearing Effect Signal (TE)
The Tearing Effect Signal (TE) is a feedback signal from the LCD Controller to MCU. This signal reveals
the display status of LCD controller. In the non-display period, the TE signal will go high. Therefore, this
signal enables the MCU to send data by observing the non-display period to avoid tearing.
Figure 7-1 shows how the TE signal helps to avoid tearing. If the MCU writing speed is slower than the
display speed, the display data should be updated after the LCD controller start to scan the frame buffer.
Then the LCD controller will always display the old memory content until the next frame. However, if the
MCU is faster than the LCD controller, it should start updating the display content in the vertical non-display
period (VNDP) to enable the LCD controller will always get the newly updated data.
SSD1963
Rev 1.1
P 17/93
Jan 2010
Solomon Systech
Figure 7-1: Relationship between Tearing Effect Signal and MCU Memory Writing
In SSD1963, users can configure the TE signal to reflect the vertical non-display period only or reflect both
vertical and horizontal non-display period. With the additional horizontal non-display period information, the
MCU can control the refresh action in more accurately by counting the horizontal line scanned by the LCD
controller. Usually, a fast MCU will not need horizontal non-display period. But a slow MCU will need it to
ensure the frame buffer update process always lags behind the LCD controller.
7.2
System Clock Generation
The system clock of SSD1963 is generated by the built-in PLL. The reference clock of the PLL can come
from either the CLK pin or the external crystal oscillator. Since the CLK pin and the output of the oscillator
was connected to PLL with an “OR” gate, the unused clock must be tied to VSS.
Before the PLL output is configured as the system clock by the bit 1 of “set_pll” command 0xE0, the system
will be clocked by the reference clock. This enables the user to send the “set_pll_mn” command 0xE2 to the
PLL for frequency configuration. When the PLL frequency is configured and the PLL was enabled with the
bit 0 of “set_pll” command 0xE0, the user should still wait for 100ms for the PLL to lock. Then the PLL is
ready and can be configured as system clock with the bit 1 of “set_pll” command 0xE0.
Solomon Systech
Jan 2010
P 18/93
Rev 1.1
SSD1963
Figure 7-2: Clock Control Diagram
set_pll bit 1
set_pll bit 0
CLK
EN
REF
PLL
1/M
1
System Clock
FB
0
OSC
XTAL_IN
XTAL_OUT
1/N
EXTERNAL
CRYSTAL
7.3
Frame Buffer
There are 1215K bytes built-in SRAM inside SSD1963 to use as frame buffer. When the frame buffer is
written or read, the “address counter” will automatically increase by one or decrease by one depends on the
frame buffer settings.
Table 7-2: Frame Buffer Settings regarding to set_address_mode command 0x36
7.4
System Clock and Reset Manager
The “System Clock and Reset Manager” distributes the reset signal and clock signal to the entire system. It
controls the Clock Generator and contains clock gating circuitry to turn on and off the clock of each
functional module. Also, it divides the root clock from Clock Generator to operation clocks for different
module. The System Clock and Reset Manager also manage the reset signals to ensure all the module are
reset to appropriate status when the system are in reset state, deep sleep state, sleep state and display state.
Figure 7-3 shows a state diagram of four operation states of SSD1963.
SSD1963
Rev 1.1
P 19/93
Jan 2010
Solomon Systech
Figure 7-3: State Diagram of SSD1963
7.5
7.5.1
LCD Controller
Display Format
The LCD controller reads the frame buffer and generates display signals according to the selected display
panel format. SSD1963 supports common RAM-less TFT driver using generic RGB data format.
7.5.2
General Purpose Input/Output (GPIO)
The GPIO pins can operate in 2 modes, GPIO mode and miscellaneous display signal mode. When the pins are
configured as GPIOs, these pins can be controlled directly by MCU. Therefore, user can use these pins to emulate other
interface such as SPI or I2C. If these pins are configured as display signals, they will toggle with display periodically
according to the signal settings. They can be set to toggle once a frame, once a line or in arbitrary period. Therefore
they can be configured as some common signal needed for different panels such as STH or LP.
Solomon Systech
Jan 2010
P 20/93
Rev 1.1
SSD1963
8
COMMAND TABLE
Hex Code
0x00
0x01
0x0A
0x0B
0x0C
0x0D
Command
nop
soft_reset
get_power_mode
get_address_mode
Reserved
get_display_mode
Description
No operation
Software Reset
Get the current power mode
Get the frame buffer to the display panel read order
Reserved
The SSD1963 returns the Display Image Mode.
0x0E
get_tear_effect_status
Get the Tear Effect status
0x0F
Reserved
Reserved
enter_sleep_mode
Turn off the panel. This command will pull low the GPIO0.
If GPIO0 is configured as normal GPIO or LCD
miscellaneous signal with command set_gpio_conf, this
command will be ignored.
0x11
exit_sleep_mode
Turn on the panel. This command will pull high the GPIO0.
If GPIO0 is configured as normal GPIO or LCD
miscellaneous signal with command set_gpio_conf, this
command will be ignored.
0x12
0x13
0x20
0x21
0x26
0x28
0x29
0x2A
0x2B
enter_partial_mode
enter_normal_mode
exit_invert_mode
enter_invert_mode
set_gamma_curve
set_display_off
set_display_on
set_column_address
set_page_address
0x2C
write_memory_start
0x2E
read_memory_start
0x30
0x33
set_partial_area
set_scroll_area
0x34
set_tear_off
0x35
set_tear_on
0x36
0x37
0x38
0x39
0x3A
set_address_mode
set_scroll_start
exit_idle_mode
enter_idle_mode
Reserved
0x3C
write_memory_continue
0x3E
read_memory_continue
0x10
SSD1963
Rev 1.1
P 21/93
Jan 2010
Part of the display area is used for image display.
The whole display area is used for image display.
Displayed image colors are not inverted.
Displayed image colors are inverted.
Selects the gamma curve used by the display panel.
Blanks the display panel
Show the image on the display panel
Set the column address
Set the page address
Transfer image information from the host processor interface
to the SSD1963 starting at the location provided by
set_column_address and set_page_address
Transfer image data from the SSD1963 to the host processor
interface starting at the location provided by
set_column_address and set_page_address
Defines the partial display area on the display panel
Defines the vertical scrolling and fixed area on display area
Synchronization information is not sent from the SSD1963 to
the host processor
Synchronization information is sent from the SSD1963 to the
host processor at the start of VFP
Set the read order from frame buffer to the display panel
Defines the vertical scrolling starting point
Full color depth is used for the display panel
Reduce color depth is used on the display panel.
Reserved
Transfer image information from the host processor interface
to the SSD1963 from the last written location
Read image data from the SSD1963 continuing after the last
read_memory_continue or read_memory_start
Solomon Systech
Hex Code
Command
Description
Synchronization information is sent from the SSD1963 to the
host processor when the display panel refresh reaches the
provided scanline
Get the current scan line
Read the DDB from the provided location
Reserved
Set the LCD panel mode and resolution
Get the current LCD panel mode, pad strength and resolution
Set front porch
Get current front porch settings
Set the vertical blanking interval between last scan line and
next LFRAME pulse
Set the vertical blanking interval between last scan line and
next LFRAME pulse
0x44
set_tear_scanline
0x45
0xA1
0xA8
0xB0
0xB1
0xB4
0xB5
get_scanline
read_ddb
Reserved
set_lcd_mode_
get_lcd_mode
set_hori_period
get_hori_period
0xB6
set_vert_period
0xB7
get_vert_period
0xB8
set_gpio_conf
0xB9
0xBA
get_gpio_conf
set_gpio_value
0xBB
get_gpio_status
0xBC
0xBD
0xBE
0xBF
set_post_proc
get_post_proc
set_pwm_conf
get_pwm_conf
0xC0
set_lcd_gen0
0xC1
get_lcd_gen0
0xC2
set_lcd_gen1
0xC3
get_lcd_gen1
0xC4
set_lcd_gen2
0xC5
get_lcd_gen2
0xC6
set_lcd_gen3
0xC7
get_lcd_gen3
0xC8
set_gpio0_rop
0xC9
get_gpio0_rop
Get the GPIO0 properties with respect to the LCD signal
generators.
0xCA
set_gpio1_rop
Set the GPIO1 with respect to the LCD signal generators
using ROP operation. No effect if the GPIO1 is configured as
general GPIO.
0xCB
get_gpio1_rop
Get the GPIO1 properties with respect to the LCD signal
generators.
0xCC
set_gpio2_rop
Set the GPIO2 with respect to the LCD signal generators
using ROP operation. No effect if the GPIO2 is configured as
general GPIO.
Solomon Systech
Set the GPIO configuration. If the GPIO is not used for LCD,
set the direction. Otherwise, they are toggled with LCD
signals.
Get the current GPIO configuration
Set GPIO value for GPIO configured as output
Read current GPIO status. If the individual GPIO was
configured as input, the value is the status of the
corresponding pin. Otherwise, it is the programmed value.
Set the image post processor
Set the image post processor
Set the image post processor
Set the image post processor
Set the rise, fall, period and toggling properties of LCD signal
generator 0
Get the current settings of LCD signal generator 0
Set the rise, fall, period and toggling properties of LCD signal
generator 1
Get the current settings of LCD signal generator 1
Set the rise, fall, period and toggling properties of LCD signal
generator 2
Get the current settings of LCD signal generator 2
Set the rise, fall, period and toggling properties of LCD signal
generator 3
Get the current settings of LCD signal generator 3
Set the GPIO0 with respect to the LCD signal generators
using ROP operation. No effect if the GPIO0 is configured as
general GPIO.
Jan 2010
P 22/93
Rev 1.1
SSD1963
Hex Code
SSD1963
Command
Description
Get the GPIO2 properties with respect to the LCD signal
generators.
0xCD
get_gpio2_rop
0xCE
set_gpio3_rop
Set the GPIO3 with respect to the LCD signal generators
using ROP operation. No effect if the GPIO3 is configured as
general GPIO.
0xCF
get_gpio3_rop
Get the GPIO3 properties with respect to the LCD signal
generators.
0xD0
set_dbc_conf
Set the dynamic back light configuration
0xD1
get_dbc_conf
Get the current dynamic back light configuration
0xD4
set_dbc_th
Set the threshold for each level of power saving
0xD5
get_dbc_th
0xE0
set_pll
0xE2
0xE3
0xE4
0xE5
0xE6
0xE7
0xE8
0xE9
set_pll_mn
get_pll_mn
get_pll_status
set_deep_sleep
set_lshift_freq
get_lshift_freq
Reserved
Reserved
0xF0
set_pixel_data_interface
0xF1
0xFF
get_pixel_data_interface
Reserved
Get the threshold for each level of power saving
Start the PLL. Before the start, the system was operated with
the crystal oscillator or clock input
Set the PLL
Get the PLL settings
Get the current PLL status
Set deep sleep mode
Set the LSHIFT (pixel clock) frequency
Get current LSHIFT (pixel clock) frequency setting
Reserved
Reserved
Set the pixel data format of the parallel host processor
interface
Get the current pixel data format settings
Reserved
Rev 1.1
P 23/93
Jan 2010
Solomon Systech
9
COMMAND DESCRIPTIONS
9.1
nop
Command
Parameters
Command
0x00
None
D/C
0
D7
0
D6
0
D5
0
D4
0
D3
0
D2
0
D1
0
D0
0
Hex
00
D7
0
D6
0
D5
0
D4
0
D3
0
D2
0
D1
0
D0
1
Hex
01
Description
No operation.
9.2
soft_reset
Command
Parameters
Command
0x01
None
D/C
0
Description
The SSD1963 performs a software reset. All the configuration register will be reset except command 0xE0 to 0xE5.
Note :
The host processor must wait 5ms before sending any new commands to a SSD1963 following this command.
9.3
get_power_mode
Command
Parameters
Command
Parameter 1
0x0A
1
D/C
0
1
D7
0
0
D6
0
A6
D5
0
A5
D4
0
A4
D3
1
A3
D2
0
A2
D1
1
0
D0
0
0
Hex
0A
xx
Description
Get the current power mode
A[6] : Idle mode on/off (POR = 0)
0
Idle mode off
1
Idle mode on
A[5] : Partial mode on/off (POR = 0)
0
Partial mode off
1
Partial mode on
A[4] : Sleep mode on/off (POR = 0)
0
Sleep mode on
1
Sleep mode off
A[3] : Display normal mode on/off (POR = 1)
0
Display normal mode off
Solomon Systech
Jan 2010
P 24/93
Rev 1.1
SSD1963
1
Display normal mode on (partial mode and vertical scroll off)
A[2] : Display on/off (POR = 0)
0
Display is off
1
Display is on
9.4
get_address_mode
Command
Parameters
Command
Parameter 1
0x0B
1
D/C
0
1
D7
0
A7
D6
0
A6
D5
0
A5
D4
0
A4
D3
1
A3
D2
0
A2
D1
1
0
D0
1
0
Hex
0B
xx
D4
0
0
D3
1
0
D2
1
A2
D1
0
A1
D0
1
A0
Hex
0D
xx
Description
Get the frame buffer to the display panel read order
A[7] : Page address order (POR = 0)
0
Top to bottom
1
Bottom to top
A[6] : Column address order (POR = 0)
0
Left to right
1
Right to left
A[5] : Page / Column order (POR = 0)
0
Normal mode
1
Reverse mode
A[4] : Line address order (POR = 0)
0
LCD refresh top to bottom
1
LCD refresh bottom to top
A[3] : RGB / BGR order (POR = 0)
0
RGB
1
BGR
A[2] : Display data latch data (POR = 0)
0
LCD refresh left to right
1
LCD refresh right to left
9.5
get_display_mode
Command
Parameters
Command
Parameter 1
0x0D
1
D/C
0
1
D7
0
A7
D6
0
0
D5
0
A5
Description
Get the Display Image Mode status.
A[7] : Vertical scrolling on/off (POR = 0)
0
Vertical scrolling is off
SSD1963
Rev 1.1
P 25/93
Jan 2010
Solomon Systech
1
Vertical scrolling is on
A[5] : Invert mode on/off (POR = 0)
0
Inversion is off
1
Inversion is on
A[2:0] : Gamma curve selection (POR = 011)
000
Gamma curve 0
001
Gamma curve 1
010
Gamma curve 2
011
Gamma curve 3
100
Reserved
101
Reserved
110
Reserved
111
Reserved
9.6
get_tear_effect_status
Command
Parameters
Command
Parameter 1
0x0E
1
D/C
0
1
D7
0
A7
D6
0
0
D5
0
0
D4
0
0
D3
1
0
D2
1
0
D1
1
0
D0
0
0
Hex
0E
xx
Description
Get the current Tear Effect mode from the SSD1963
A[7] : Tearing effect line mode (POR = 0)
0
Tearing effect off
1
Tearing effect on
Solomon Systech
Jan 2010
P 26/93
Rev 1.1
SSD1963
9.7
enter_sleep_mode
Command
Parameters
Command
0x10
None
D/C
0
D7
0
D6
0
D5
0
D4
1
D3
0
D2
0
D1
0
D0
0
Hex
10
Description
Turn off the panel. This command causes the SSD1963 to enter sleep mode and pull low the GPIO[0] if set_gpio_conf
(0xB8) B0 = 0
If GPIO[0] is configured as normal GPIO or LCD miscellaneous signal with command set_gpio_conf (0xB8), this
command will not affect the GPIO[0].
Note :
The host processor must wait 5ms before sending any new commands to a SSD1963 following this command.
9.8
exit_sleep_mode
Command
Parameters
Command
0x11
None
D/C
0
D7
0
D6
0
D5
0
D4
1
D3
0
D2
0
D1
0
D0
1
Hex
11
Description
Turn on the panel. This command causes the SSD1963 to exit sleep mode and will pull high the GPIO[0] if
set_gpio_conf (0xB8) B0 = 0.
If GPIO[0] is configured as normal GPIO or LCD miscellaneous signal with command set_gpio_conf (0xB8), this
command will not affect the GPIO[0].
Note :
The host processor must wait 5ms after sending this command before sending another command.
**This command will automatic trigger set_display_on (0x29)
9.9
enter_partial_mode
Command
Parameters
Command
0x12
None
D/C
0
D7
0
D6
0
D5
0
D4
1
D3
0
D2
0
D1
1
D0
0
Hex
12
Description
Once enter_partial_mode is triggered, the Partial Display Mode window is described by the set_partial_area (0x30).
Once enter_normal_mode (0x13) is triggered, partial display mode will end.
9.10 enter_normal_mode
Command
Parameters
SSD1963
0x13
None
Rev 1.1
P 27/93
Jan 2010
Solomon Systech
Command
D/C
0
D7
0
D6
0
D5
0
D4
1
D3
0
D2
0
D1
1
D0
1
Hex
13
Description
This command causes the SSD1963 to enter the normal mode. Normal mode is defined as partial display and vertical
scroll mode are off. That means the whole display area is used for image display.
9.11 exit_invert_mode
Command
Parameters
Command
0x20
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
0
D2
0
D1
0
D0
0
Hex
20
Description
This command causes the SSD1963 to stop inverting the image data on the display panel. The frame buffer contents
remain unchanged.
Figure 9-1: Exit Invert mode example
Frame Buffer
Display Panel
Ö
9.12 enter_invert_mode
Command
Parameters
Command
0x21
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
0
D2
0
D1
0
D0
1
Hex
21
Description
This command causes the SSD1963 to invert the image data only on the display panel. The frame buffer contents remain
unchanged.
Solomon Systech
Jan 2010
P 28/93
Rev 1.1
SSD1963
Figure 9-2: Enter Invert mode example
Frame Buffer
Display Panel
Ö
9.13 set_gamma_curve
Command
Parameters
Command
Parameter 1
0x26
1
D/C
0
1
D7
0
0
D6
0
0
D5
1
0
D4
0
0
D3
0
A3
D2
1
A2
D1
1
A1
D0
0
A0
Hex
26
xx
Description
Selects the gamma curve used by the display panel.
A[3:0]
0000
0001
0010
0100
1000
Others
Gamma curve selection (POR = 1000)
No gamma curve selected (Same as 0001b)
Gamma curve 0
Gamma curve 1
Gamma curve 2
Gamma curve 3
Reserved
GAMAS[1]
0
0
0
1
1
GAMAS[0]
0
0
1
0
1
9.14 set_display_off
Command
Parameters
Command
0x28
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
1
D2
0
D1
0
D0
0
Hex
28
D2
0
D1
0
D0
1
Hex
29
Description
Blanks the display panel. The frame buffer contents remain unchanged.
9.15 set_display_on
Command
Parameters
Command
0x29
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
1
Description
Show the image on the display panel
SSD1963
Rev 1.1
P 29/93
Jan 2010
Solomon Systech
9.16 set_column_address
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
0x2A
4
D/C
0
1
1
1
1
D7
0
SC15
SC7
EC15
EC7
D6
0
SC14
SC6
EC14
EC6
D5
1
SC13
SC5
EC13
EC5
D4
0
SC12
SC4
EC12
EC4
D3
1
SC11
SC3
EC11
EC3
D2
0
SC10
SC2
EC10
EC2
D1
1
SC9
SC1
EC9
EC1
D0
0
SC8
SC0
EC8
EC0
Hex
2A
xx
xx
xx
xx
Description
Set the column address of frame buffer accessed by the host processor with the read_memory_continue (0x3E) and
write_memorty_continue (0x3C)..
SC[15:8] : Start column number high byte (POR = 00000000)
SC[7:0] : Start column number low byte (POR = 00000000)
EC[15:8] : End column number high byte (POR = 00000000)
EC[7:0] : End column number low byte (POR = 00000000)
Note : SC[15:0] must always be equal to or less than EC[15:0]
SC[15:0]
EC[15:0]
Figure 9-3: Set Column Address example
9.17 set_page_address
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
0x2B
4
D/C
0
1
1
1
1
D7
0
SP15
SP7
EP15
EP7
D6
0
SP14
SP6
EP14
EP6
D5
1
SP13
SP5
EP13
EP5
D4
0
SP12
SP4
EP12
EP4
D3
1
SP11
SP3
EP11
EP3
D2
0
SP10
SP2
EP10
EP2
D1
0
SP9
SP1
EP9
EP1
D0
1
SP8
SP0
EP8
EP0
Hex
2B
xx
xx
xx
xx
Description
Set the page address of the frame buffer accessed by the host processor with the read_memory_start (0x2C),
write_memory_start (0x2E), read_memory_continue (0x3E) and write_memory_continue (0x3C)..
Solomon Systech
Jan 2010
P 30/93
Rev 1.1
SSD1963
SP[15:8] : Start page (row) number high byte (POR = 00000000)
SP[7:0] : Start page (row) number low byte (POR = 00000000)
EP[15:8] : End page (row) number high byte (POR = 00000000)
EP[7:0] : End page (row) number low byte (POR = 00000000)
Note : SP[15:0] must always be equal to or less than EP[15:0]
Figure 9-4: Set Page Address example
SP[15:0]
EP[15:0]
9.18 write_memory_start
Command
Parameters
Command
0x2C
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
1
D2
1
D1
0
D0
0
Hex
2C
Description
Transfer image information from the host processor interface to the SSD1963 starting at the location provided by
set_column _address (0x2A) and set _page_address (0x2B).
If set_address_mdoe (0x36) A[5] = 0:
The column and page address are reset to the Start Column (SC) and Start Page (SP), respectively.
Pixel Data 1 is stored in frame buffer at (SC, SP). The column address is then incremented and pixels are written to the
frame buffer until the column address equals the End Column (EC) value. The column address is then reset to SC and the
page address is incremented. Pixels are written to the frame buffer until the page address equals the End Page (EP) value
and the column address equals the EC value, or the host processor sends another command. If the number of pixels
exceeds (EC – SC + 1) * (EP – SP + 1) the extra pixels are ignored.
If set_address_mode (0x36) A[5] = 1:
The column and page address are reset to the Start Column (SC) and Start Page (SP), respectively.
Pixel Data 1 is stored in frame buffer at (SC, SP). The page address is then incremented and pixels are written to the
frame buffer until the page address equals the End Page (EP) value. The page address is then reset to SP and the column
address is incremented. Pixels are written to the frame buffer until the column address equals the End column (EC) value
and the page address equals the EP value, or the host processor sends another command. If the number of pixels exceeds
(EC – SC + 1) * (EP – SP + 1) the extra pixels are ignored.
SSD1963
Rev 1.1
P 31/93
Jan 2010
Solomon Systech
9.19 read_memory_start
Command
Parameters
Command
0x2E
None
D/C
0
D7
0
D6
0
D5
1
D4
0
D3
1
D2
1
D1
1
D0
0
Hex
2E
Description
Transfer image data from the SSD1963 to the host processor interface starting at the location provided by
set_column_address (0x2A) and set_page_address (0x2B).
If set_address_mode A[5] = 0:
The column and page address are reset to the Start Column (SC) and Start Page (SP), respectively.
Pixels Data 1 are read from frame buffer at (SC, SP). The column address is then incremented and pixels read from the
frame buffer until the column address equals the End Column (EC) value. The column address is then reset to SC and the
page address is incremented. Pixels are read from the frame buffer until the page address equals the End Page (EP) value
and the column address equals the EC value, or the host processor sends another command.
If set_address_mode (0x36) A[5] = 1:
The column and page address are reset to the Start Column (SC) and Start Page (SP), respectively.
Pixels Data 1 are read from frame buffer at (SC, SP). The page address is then incremented and pixels read from the
frame buffer until the page address equals the End Page (EP) value. The page address is then reset to SP and the column
address is incremented. Pixels are read from the frame buffer until the column address equals the End Column (EC)
value and the page address equals the EP value, or the host processor sends another command.
9.20 set_partial_area
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
0x30
4
D/C
0
1
1
1
1
D7
0
SR15
SR7
ER15
ER7
D6
0
SR14
SR6
ER14
ER6
D5
1
SR13
SR5
ER13
ER5
D4
1
SR12
SR4
ER12
ER4
D3
0
SR11
SR3
ER11
ER3
D2
0
SR10
SR2
ER10
ER2
D1
0
SR9
SR1
ER9
ER1
D0
0
SR8
SR0
ER8
ER0
Hex
30
xx
xx
xx
xx
Description
This command defines the Partial Display mode’s display area. There are two parameters associated with this command,
the first defines the Start Row (SR) and the second the End Row (ER). SR and ER refer to the Frame Buffer Line Pointer.
SR[15:8] : Start display row number high byte (POR = 00000000)
SR[7:0] : Start display row number low byte (POR = 00000000)
ER[15:8] : End display row number high byte (POR = 00000000)
ER[7:0] : End display row number low byte (POR = 00000000)
Note : SR[15:0] and ER[15:0] cannot be 0000h nor exceed the last vertical line number.
If End Row > Start Row
Solomon Systech
Jan 2010
P 32/93
Rev 1.1
SSD1963
Figure 9-5: Set Partial Area with set_address_mode (0x36) A[4] = 0 when End Row > Start Row
SR[15:0]
Partial Area
ER[15:0]
Figure 9-6: Set Partial Area with set_address_mode (0x36) A[4] = 1 when End Row > Start Row
ER[15:0]
Partial Area
SR[15:0]
If Start Row > End Row
Figure 9-7: Set Partial Area with set_address_mode (0x36) A[4] = 0 when Start Row > End Row
Partial Area
ER[15:0]
SR[15:0]
Partial Area
Figure 9-8: Set Partial Area with set_address_mode (0x36) A[4] = 1 when Start Row > End Row
SSD1963
Rev 1.1
P 33/93
Jan 2010
Solomon Systech
Partial Area
SR[15:0]
ER[15:0]
Partial Area
9.21 set_scroll_area
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
0x33
6
D/C
0
1
1
1
1
1
1
D7
0
TFA15
TFA7
VSA15
VSA7
BFA15
BFA7
D6
0
TFA14
TFA6
VSA14
VSA6
BFA14
BFA6
D5
1
TFA13
TFA5
VSA13
VSA5
BFA13
BFA5
D4
1
TFA12
TFA4
VSA12
VSA4
BFA12
BFA4
D3
0
TFA11
TFA3
VSA11
VSA3
BFA11
BFA3
D2
0
TFA10
TFA2
VSA10
VSA2
BFA10
BFA2
D1
1
TFA9
TFA1
VSA9
VSA1
BFA9
BFA1
D0
1
TFA8
TFA0
VSA8
VSA0
BFA8
BFA0
Hex
33
xx
xx
xx
xx
xx
xx
Description
Defines the vertical scrolling and fixed area on display area
TFA[15:8] : High byte of Top Fixed Area number in lines from the top of the frame buffer (POR = 00000000)
TFA[7:0] : Low byte of Top Fixed Area number in lines from the top of the frame buffer (POR = 00000000)
VSA[15:8] : High byte of Vertical scrolling area in number of lines of the frame buffer (POR = 00000000)
VSA[7:0] : Low byte of Vertical scrolling area in number of lines of the frame buffer (POR = 00000000)
BFA[15:8] : High byte of Bottom Fixed Area in number of lines from the bottom of the frame buffer (POR = 00000000)
BFA[7:0] : Low byte of Bottom Fixed Area in number of lines from the bottom of the frame buffer (POR = 00000000)
If set_address_mode (0x36) A[4] = 0 :
The TFA[15:0] describes the Top Fixed Area in number of lines from the top of the frame buffer. The top of the frame
buffer and top of the display panel are aligned.
The VSA[15:0] describes the height of the Vertical Scrolling Area in number of lines of frame buffer from the Vertical
Scrolling Start Address. The first line of the Vertical Scrolling Area starts immediately after the bottom most line of the
Top Fixed Area. The last line of the Vertical Scrolling Area ends immediately before the top most line of the Bottom
Fixed Area.
The BFA[15:0] describes the Bottom Fixed Area in number of lines from the bottom of the frame buffer. The bottom of
the frame buffer and bottom of the display panel are aligned.
TFA, VSA and BFA refer to the Frame Buffer Line Pointer.
Solomon Systech
Jan 2010
P 34/93
Rev 1.1
SSD1963
Figure 9-9: Set Scroll Area with set_address_mode (0x36) A[4] = 0
(0,0)
Top Fixed Area
TFA[15:0]
First line read from memory
VSA[15:0]
BFA[15:0]
Bottom Fixed Area
If set_address_mode (0x36) A[4] = 1 :
The TFA[15:0], describes the Top Fixed Area in number of lines from the bottom of the frame buffer. The bottom of the
frame buffer and bottom of the display panel are aligned.
The VSA[15:0] describes the height of the Vertical Scrolling Area in number of lines of frame buffer from the Vertical
Scrolling Start Address. The first line of the Vertical Scrolling Area starts immediately after the top most line of the Top
Fixed Area. The last line of the Vertical Scrolling Area ends immediately before the bottom most line of the Bottom
Fixed Area.
The BFA[15:0] describes the Bottom Fixed Area in number of lines from the top of the frame buffer. The top of the
frame buffer and top of the display panel are aligned.
TFA, VSA and BFA refer to the Frame Buffer Line Pointer.
Figure 9-10: Set Scroll Area with set_address_mode (0x36) A[4] = 1
(0,0)
Bottom Fixed Area
BFA[15:0]
VSA[15:0]
First line read from memory
TFA[15:0]
Top Fixed Area
Note :
The sum of TFA, VSA and BFA must equal the number of the display panel’s horizontal lines (pages), otherwise
Scrolling mode is undefined.
In Vertical Scroll Mode, set_address_mode (0x36) A[5] should be set to ‘0’ – this only affects the Frame Buffer Write.
SSD1963
Rev 1.1
P 35/93
Jan 2010
Solomon Systech
9.22 set_tear_off
Command
Parameters
Command
0x34
None
D/C
0
D7
0
D6
0
D5
1
D4
1
D3
0
D2
1
D1
0
D0
0
Hex
34
D3
0
0
D2
1
0
D1
0
0
D0
1
A0
Hex
35
xx
Description
TE signal is not sent from the SSD1963 to the host processor.
9.23 set_tear_on
Command
Parameters
Command
Parameter 1
0x35
1
D/C
0
1
D7
0
0
D6
0
0
D5
1
0
D4
1
0
Description
TE signal is sent from the SSD1963 to the host processor at the start of VFP.
A[0] : Tearing effect line mode (POR = 0)
0
The tearing effect output line consists of V-blanking information only.
1
The tearing effect output line consists of both V-blanking and H-blanking information by
set_tear_scanline (0x44).
The TE signal shall be active low when the display panel is in Sleep mode.
9.24 set_address_mode
Command
Parameters
Command
Parameter 1
0x36
1
D/C
0
1
D7
0
A7
D6
0
A6
D5
1
A5
D4
1
A4
D3
0
A3
D2
1
A2
D1
1
A1
D0
0
A0
Hex
36
xx
Description
Set the read order from host processor to frame buffer by A[7:5] and A[3] and from frame buffer to the display panel by
A[2:0] and A[4].
A[7] : Page address order (POR = 0)
This bit controls the order that pages of data are transferred from the host processor to the SSD1963’s frame buffer.
0
Top to bottom, pages transferred from SP (Start Page) to EP (End Page).
1
Bottom to top, pages transferred from EP (End Page) to SP (Start Page).
Solomon Systech
Jan 2010
P 36/93
Rev 1.1
SSD1963
Figure 9-11: A[7] Page Address Order
Host
A[7]=0,
A[6]=A[5]=0,A[3]=x
Frame Buffer
SP
Host
SP


EP
SC

EC
A[7]=1,
A[6]=A[5]=0,A[3]=x
Frame Buffer
SP

EP

SC
EC
EP

EP
SC

EC
SP
SC

EC
A[6] : Column address order (POR = 0)
This bit controls the order that columns of data are transferred from the host processor to the SSD1963’s frame buffer.
0
Left to right, columns transferred from SC (Start Column) to EC (End Column).
1
Right to left, columns transferred from EC (End Column) to SC (Start Column).
Figure 9-12: A[6] Column Address Order
Host
SC

A[6]=0,
A[7]=A[5]=0,A[3]=x
Frame Buffer
SP
Host
SP
A[6]=1,
A[7]=A[5]=0,A[3]=x
Frame Buffer
SP
SP




EP
EP
EP
EP
EC

SC
EC
SC

EC
EC

SC
A[5] : Page / Column order (POR = 0)
This bit controls the order that columns of data are transferred from the host processor to the SSD1963’s frame buffer.
0
Normal mode
1
Reverse mode
Figure 9-13: A[5] Page / Column Address Order
Host
A[5]=0,
A[7]=A[6]=0,A[3]=x
Frame Buffer
SP
Host
SP


EP
SC

SSD1963
EC
Rev 1.1
A[5]=1,
A[7]=A[6]=0,A[3]=x
Frame Buffer
SP

EP
SC
P 37/93

Jan 2010
EC
SC

EC
EP
SC

EC
SP

EP
Solomon Systech
A[4] : Line address order (POR = 0)
This bit controls the display panel’s horizontal line refresh order. The image shown on the display panel is unaffected,
regardless of the bit setting.
0
LCD refresh from top line to bottom line.
1
LCD refresh from bottom line to top line.
A[3] : RGB / BGR order (POR = 0)
This bit controls the RGB data order transferred from the SSD1963’s frame buffer to the display panel.
0
RGB
1
BGR
Figure 9-14: A[3] RGB Order
A[3] = 0
Frame Buffer
R
G
A[3] = 1
Display Panel

B
R
G
Frame Buffer
B
R
G
Display Panel

B
B
G
R
A[2] : Display data latch data (POR = 0)
This bit controls the display panel’s vertical line data latch order. The image shown on the display panel is unaffected,
regardless of the bit setting.
0
LCD refresh from left side to right side
1
LCD refresh from right side to left side
A[1] : Flip Horizontal (POR = 0)
This bit flips the image shown on the display panel left to right. No change is made to the frame buffer.
0
Normal
1
Flipped
Figure 9-15: A[1] Flip Horizontal
Frame Buffer
1

A[1]=0,
A[4]=A[2]=A[0]=0
Display Panel
1
m
Solomon Systech
Frame Buffer
1
A[1]=1,
A[4]=A[2]=A[0]=0
Display Panel
1
1




n
n
n
n
1

m
1

Jan 2010
m
m
P 38/93
Rev 1.1

SSD1963
1
A[0] : Flip Vertical (POR = 0)
This bit flips the image shown on the display panel top to bottom. No change is made to the frame buffer.
0
Normal
1
Flipped
Figure 9-16: A[0] Flip Vertical
Frame Buffer
A[0]=0,
A[4]=A[2]=A[1]=0
Display Panel
1
1


n
1

A[0]=1,
A[4]=A[2]=A[1]=0
Frame Buffer
Display Panel
1

n
m
1

m
n

n
1

m
1
1

m
9.25 set_scroll_start
Command
Parameters
Command
Parameter 1
Parameter 2
0x37
2
D/C
0
1
1
D7
0
VSP15
VSP7
D6
0
VSP14
VSP6
D5
1
VSP13
VSP5
D4
1
VSP12
VSP4
D3
0
VSP11
VSP3
D2
1
VSP10
VSP2
D1
1
VSP9
VSP1
D0
1
VSP8
VSP0
Hex
37
xx
xx
Description
This command sets the start of the vertical scrolling area in the frame buffer. The vertical scrolling area is fully defined
when this command is used with the set_scroll_area (0x33).
VSP[15:8] : High byte of the line number in frame buffer that is written to the display as the first line of the vertical
scrolling area (POR = 00000000)
VSP[7:0] : Low byte of the line number in frame buffer that is written to the display as the first line of the vertical
scrolling area (POR = 00000000)
If set_address_mode (0x36) A[4] = 0:
Example:
When Top Fixed Area = Bottom Fixed Area = 0, Vertical Scrolling Area = YY and VSP = 3.
Figure 9-17: Set Scroll Start with set_address_mode (0x36) A[4] = 0
Frame Buffer
(0,0)
Display Panel
VSP[15:0]
VSP[15:0]
(0,YY-1)
(0,0)
(0,YY-1)
SSD1963
Rev 1.1
P 39/93
Jan 2010
Solomon Systech
If set_address_mode (0x36) A[4] = 1:
Example:
When Top Fixed Area = Bottom Fixed Area = 0, Vertical Scrolling Area = YY and VSP = 3.
Figure 9-18: Set Scroll Start with set_address_mode (0x36) A[4] = 1
Frame Buffer
Display Panel
(0,YY-1)
(0,0)
(0,YY-1)
VSP[15:0]
(0,0)
VSP[15:0]
Note :
If set_address_mode, (0x36) A[4] = 0, TFA[15:0] - 1< VSP[15:0] < # of lines in frame buffer - BFA[15:0]
If set_address_mode, (0x36) A[4] = 1, BFA[15:0] - 1 < VSP[15:0] < # of lines in frame buffer - TFA[15:0]
9.26 exit_idle_mode
Command
Parameters
Command
0x38
None
D/C
0
D7
0
D6
0
D5
1
D4
1
D3
1
D2
0
D1
0
D0
0
Hex
38
D4
1
D3
1
D2
0
D1
0
D0
1
Hex
39
Description
This command causes the SSD1963 to exit Idle Mode.
Full color depth is used for the display panel.
9.27 enter_idle_mode
Command
Parameters
Command
0x39
None
D/C
0
D7
0
D6
0
D5
1
Description
This command causes the SSD1963 to enter Idle Mode.
In Idle Mode, color depth is reduced. Colors are shown on the display panel using the MSB of each of the R, G and B
color components in the frame buffer.
Solomon Systech
Jan 2010
P 40/93
Rev 1.1
SSD1963
Table 9-1 Enter Idle Mode memory content vs display color
Color
R7 R6 R5 R4 R3 R2 R1 R0
G7 G6 G5 G4 G3 G2 G1 G0
B7 B6 B5 B4 B3 B2 B1 B0
Black
0XXXXXXX
0XXXXXXX
0XXXXXXX
Blue
0XXXXXXX
0XXXXXXX
1XXXXXXX
Red
1XXXXXXX
0XXXXXXX
0XXXXXXX
Magenta
1XXXXXXX
0XXXXXXX
1XXXXXXX
Green
0XXXXXXX
1XXXXXXX
0XXXXXXX
Cyan
0XXXXXXX
1XXXXXXX
1XXXXXXX
Yellow
1XXXXXXX
1XXXXXXX
0XXXXXXX
White
1XXXXXXX
1XXXXXXX
1XXXXXXX
9.28 write_memory_continue
Command
Parameters
Command
0x3C
None
D/C
0
D7
0
D6
0
D5
1
D4
1
D3
1
D2
1
D1
0
D0
0
Hex
3C
Description
Transfer image information from the host processor interface to the SSD1963 from the last write_memory_continue
(0x3C) or write_memory_start (0x2C).
If set_address_mode (0x36) A[5] = 0:
Data is written continuing from the pixel location after the write range of the previous write_memory_start (0x2C) or
write_memory_continue (0x3C). The column address is then incremented and pixels are written to the frame buffer until
the column address equals the End Column (EC) value. The column address is then reset to SC and the page address is
incremented. Pixels are written to the frame buffer until the page address equals the End Page (EP) value and the column
address equals the EC value, or the host processor sends another command. If the number of pixels exceeds (EC – SC +
1) * (EP – SP + 1) the extra pixels are ignored.
If set_address_mode (0x36) A[5] = 1:
Data is written continuing from the pixel location after the write range of the previous write_memory_start (0x2C) or
write_memory_continue (0x3C). The page address is then incremented and pixels are written to the frame buffer until
the page address equals the End Page (EP) value. The page address is then reset to SP and the column address is
incremented. Pixels are written to the frame buffer until the column register equals the End column (EC) value and the
page address equals the EP value, or the host processor sends another command. If the number of pixels exceeds (EC –
SC + 1) * (EP – SP + 1) the extra pixels are ignored.
SSD1963
Rev 1.1
P 41/93
Jan 2010
Solomon Systech
9.29 read_memory_continue
Command
Parameters
Command
0x3E
None
D/C
0
D7
0
D6
0
D5
1
D4
1
D3
1
D2
1
D1
1
D0
0
Hex
3E
Description
Read image data from the SSD1963 to host processor continuing after the last read_memory_continue (0x3E) or
read_memory_start (0x2E).
If set_address_mode (0x36) A[5] = 0:
Pixels are read continuing from the pixel location after the read range of the previous read_memory_start (0x2E) or
read_memory_continue (0x3E). The column address is then incremented and pixels are read from the frame buffer until
the column address equals the End Column (EC) value. The column address is then reset to SC and the page address is
incremented. Pixels are read from the frame buffer until the page address equals the End Page (EP) value and the column
address equals the EC value, or the host processor sends another command.
If set_address_mode (0x36) A[5] = 1:
Pixels are read continuing from the pixel location after the read range of the previous read_memory_start (0x2E) or
read_memory_continue (0x3E). The page address is then incremented and pixels are read from the frame buffer until the
page address equals the End Page (EP) value. The page address is then reset to SP and the column address is
incremented. Pixels are read from the frame buffer until the column address equals the End Column (EC) value and the
page address equals the EP value, or the host processor sends another command.
Solomon Systech
Jan 2010
P 42/93
Rev 1.1
SSD1963
9.30 set_tear_scanline
Command
Parameters
Command
Parameter 1
Parameter 2
0x44
2
D/C
0
1
1
D7
0
N15
N7
D6
1
N14
N6
D5
0
N13
N5
D4
0
N12
N4
D3
0
N11
N3
D2
1
N10
N2
D1
0
N9
N1
D0
0
N8
N0
Hex
44
xx
xx
Description
TE signal is sent from the SSD1963 to the host processor when the display panel refresh reaches the provided scanline,
N.
N[15:8] : High byte of the scanline (POR = 00000000)
N[7:0] : Low byte of the scanline (POR = 00000000)
Note :
Set Tear Scanline with N = 0 is equivalent to set_tear_on (0x35) A[0] = 0.
This command takes affect on the frame following the current frame. Therefore, if the Tear Effect (TE) signal is already
ON, the TE output shall continue to operate as programmed by the previous set_tear_on (0x35) or set_tear_scanline
(0x44) until the end of the frame.
9.31 get_scanline
Command
Parameters
Command
Parameter 1
Parameter 2
0x45
2
D/C
0
1
1
D7
0
N15
N7
D6
1
N14
N6
D5
0
N13
N5
D4
0
N12
N4
D3
0
N11
N3
D2
1
N10
N2
D1
0
N9
N1
D0
1
N8
N0
Hex
45
xx
xx
Description
Get the current scan line, N.
N[15:8] : High byte of the current scanline (POR = 00000000)
N[7:0] : Low byte of the current scanline (POR = 00000000)
SSD1963
Rev 1.1
P 43/93
Jan 2010
Solomon Systech
9.32 read_ddb
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
0xA1
5
D/C
0
1
1
1
1
1
D7
1
SSL15
SSL7
PROD7
0
1
D6
0
SSL14
SSL6
PROD6
0
1
D5
1
SSL13
SSL5
PROD5
0
1
D4
0
SSL12
SSL4
PROD4
0
1
D3
0
SSL11
SSL3
PROD3
0
1
D2
0
SSL10
SSL2
PROD2
REV2
1
D1
0
SSL9
SSL1
PROD1
REV 1
1
D0
1
SSL8
SSL0
PROD0
REV 0
1
Hex
A1
xx
xx
xx
xx
FF
D0
0
A0
0
HDP8
HDP0
VDP8
VDP0
G0
Hex
B0
xx
xx
xx
xx
xx
xx
xx
Description
Read the DDB (Device Descriptor Block) information of SSD1963.
SSL[15:8] : Supplier ID of Solomon Systech Limited high byte, always 01h (POR = 00000001)
SSL[7:0] : Supplier ID of Solomon Systech Limited low byte, always 57h (POR = 010101110)
PROD[7:0] : Product ID, always 61h (POR = 01100001)
REV[2:0] : Revision code, always 01h (POR = 001)
Exit code, always FFh (POR = 11111111)
9.33 set_lcd_mode
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xB0
7
D/C
0
1
1
1
1
1
1
1
D7
1
0
0
0
HDP7
0
VDP7
0
D6
0
0
B6
0
HDP6
0
VDP6
0
D5
1
A5
B5
0
HDP5
0
VDP5
G5
D4
1
A4
0
0
HDP4
0
VDP4
G4
D3
0
A3
0
0
HDP3
0
VDP3
G3
D2
0
A2
0
HDP10
HDP2
VDP10
VDP2
G2
D1
0
A1
0
HDP9
HDP1
VDP9
VDP1
G1
Description
Set the LCD panel mode and resolution
A[5] : TFT panel data width (POR = 0)
0
18-bit
1
24-bit
A[4] : TFT color depth enhancement enable (POR = 0)
0
Disable FRC or dithering
1
Enable FRC or dithering for color depth enhancement
If the panel data width was set to 24-bit, FRC and dithering feature will be disabled automatic regardless the value of this
register.
A[3] : TFT FRC enable (POR = 0)
0
TFT dithering enable
1
TFT FRC enable
Solomon Systech
Jan 2010
P 44/93
Rev 1.1
SSD1963
A[5]
0
0
0
1
A[4]
0
1
1
X
A[3]
X
0
1
X
TFT FRC
Disable
Disable
Enable
Disable
TFT dithering
Disable
Enable
Disable
Disable
A[2] : LSHIFT polarity (POR = 0)
Set the dot clock pulse polarity.
0
Data latch in falling edge
1
Data latch in rising edge
A[1] : LLINE polarity (POR = 0)
Set the horizontal sync pulse polarity.
0
Active low
1
Active high
A[0] : LFRAME polarity (POR = 0)
Set the vertical sync pulse polarity.
0
Active low
1
Active high
B[6:5] : TFT type (POR = 01)
00, 01 TFT mode
10
Serial RGB mode
11
Serial RGB+dummy mode
HDP [10:8] : High byte of the horizontal panel size (POR = 010)
HDP [7:0] : Low byte of the horizontal panel size (POR = 01111111)
Horizontal panel size = (HDP + 1) pixels
VDP [10:8] : High byte of the vertical panel size (POR = 001)
VDP [7:0] : Low byte of the vertical panel size (POR = 11011111)
Vertical panel size = (VDP + 1) lines
G[5:3] : Even line RGB sequence for serial TFT interface (POR = 000)
000
RGB
001
RBG
010
GRB
011
GBR
100
BRG
101
BGR
11x
Reserved
G[2:0] : Odd line RGB sequence for serial TFT interface (POR = 000)
000
RGB
001
RBG
010
GRB
011
GBR
100
BRG
101
BGR
11x
Reserved
SSD1963
Rev 1.1
P 45/93
Jan 2010
Solomon Systech
9.34 get_lcd_mode
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xB1
7
D/C
0
1
1
1
1
1
1
1
D7
1
0
0
0
HDP7
0
VDP7
0
D6
0
0
B6
0
HDP6
0
VDP6
0
D5
1
A5
B5
0
HDP5
0
VDP5
G5
D4
1
A4
0
0
HDP4
0
VDP4
G4
D3
0
A3
0
0
HDP3
0
VDP3
G3
D2
0
A2
0
HDP10
HDP2
VDP10
VDP2
G2
D1
0
A1
0
HDP9
HDP1
VDP9
VDP1
G1
D0
1
A0
0
HDP8
HDP0
VDP8
VDP0
G0
Hex
B1
xx
xx
xx
xx
xx
xx
xx
Description
Get the current LCD panel mode and resolution
A[5] : TFT panel data width(POR = 0)
0
18-bit
1
24-bit
A[4] : TFT color depth enhancement enable(POR = 0)
0
Disable FRC or dithering
1
Enable FRC or dithering for color depth enhancement
If the panel data width was set to 24-bit, FRC and dithering feature will be disabled automatic regardless the value of this
register.
A[3] : TFT FRC enable (POR = 0)
0
TFT dithering enable
1
TFT FRC enable
A[2] : LSHIFT polarity (POR = 0)
The dot clock pulse polarity.
0
Data latch in falling edge
1
Data latch in rising edge
A[1] : LLINE polarity (POR = 0)
The horizontal sync pulse polarity.
0
Active low
1
Active high
A[0] : LFRAME polarity (POR = 0)
The vertical sync pulse polarity.
0
Active low
1
Active high
B[6:5] : TFT type(POR = 01)
00, 01 TFT mode
10
Serial RGB mode
11
Serial RGB+dummy mode
HDP[10:8] : High byte of the horizontal panel size (POR = 010)
HDP[7:0] : Low byte of the horizontal panel size (POR = 01111111)
VDP[10:8] : High byte of the vertical panel size (POR = 001)
Solomon Systech
Jan 2010
P 46/93
Rev 1.1
SSD1963
VDP[7:0] : Low byte of the vertical panel size (POR = 11011111)
G[5:3] : Even line RGB sequence (POR = 000)
000
RGB
001
RBG
010
GRB
011
GBR
100
BRG
101
BGR
11x
Reserved
G[2:0] : Odd line RGB sequence (POR = 000)
000
RGB
001
RBG
010
GRB
011
GBR
100
BRG
101
BGR
11x
Reserved
9.35 set_hori_period
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
Parameter 8
0xB4
8
D/C
0
1
1
1
1
1
1
1
1
D7
1
0
HT7
0
HPS7
0
0
LPS7
0
D6
0
0
HT6
0
HPS6
HPW6
0
LPS6
0
D5
1
0
HT5
0
HPS5
HPW5
0
LPS5
0
D4
1
0
HT4
0
HPS4
HPW4
0
LPS4
0
D3
0
0
HT3
0
HPS3
HPW3
0
LPS3
0
D2
1
HT10
HT2
HPS10
HPS2
HPW2
LPS10
LPS2
0
D1
0
HT9
HT1
HPS9
HPS1
HPW1
LPS9
LPS1
LPSPP1
D0
0
HT8
HT0
HPS8
HPS0
HPW0
LPS8
LPS0
LPSPP0
Hex
B4
xx
xx
xx
xx
xx
xx
xx
xx
Description
Set front porch and back porch
HT[10:8] :
HT[7:0] :
High byte of horizontal total period (display + non-display) in pixel clock (POR = 010)
Low byte of the horizontal total period (display + non-display) in pixel clock (POR = 10101111)
Horizontal total period = (HT + 1) pixels
HPS[10:8] :
High byte of the non-display period between the start of the horizontal sync (LLINE) signal and the first
display data. (POR = 000)
Low byte of the non-display period between the start of the horizontal sync (LLINE) signal and the first
display data. (POR = 00100000)
For TFT : Horizontal Sync Pulse Start Position = HPS pixels
For Serial TFT : Horizontal Sync Pulse Start Position = HPS pixels + LPSPP subpixels
HPS[7:0] :
HPW[6:0] :
SSD1963
Set the horizontal sync pulse width (LLINE) in pixel clock. (POR = 0000111)
Horizontal Sync Pulse Width = (HPW + 1) pixels
Rev 1.1
P 47/93
Jan 2010
Solomon Systech
LPS[10:8] :
LPS[7:0] :
Set the horizontal sync pulse (LLINE) start location in pixel clock. (POR = 000)
Set the horizontal sync pulse width (LLINE) in start. (POR = 00000000)
Horizontal Display Period Start Position = LPS pixels
LPSPP[1:0] : Set the horizontal sync pulse subpixel start position for serial TFT interface (POR = 00)
Timing refer to Figure 13-5.
9.36 get_hori_period
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
Parameter 8
0xB5
8
D/C
0
1
1
1
1
1
1
1
1
D7
1
0
HT7
0
HPS7
0
0
LPS7
0
D6
0
0
HT6
0
HPS6
HPW6
0
LPS6
0
D5
1
0
HT5
0
HPS5
HPW5
0
LPS5
0
D4
1
0
HT4
0
HPS4
HPW4
0
LPS4
0
D3
0
0
HT3
0
HPS3
HPW3
0
LPS3
0
D2
1
HT10
HT2
HPS10
HPS2
HPW2
LPS10
LPS2
0
D1
0
HT9
HT1
HPS9
HPS1
HPW1
LPS9
LPS1
LPSPP1
D0
1
HT8
HT0
HPS8
HPS0
HPW0
LPS8
LPS0
LPSPP0
Hex
B5
xx
xx
xx
xx
xx
xx
xx
xx
Description
Get current front porch and back porch settings
HT[10:8] :
HT[7:0] :
High byte of the horizontal total period (display + non-display) in pixel clock (POR = 010)
Low byte of the horizontal total period (display + non-display) in pixel clock (POR = 10101111)
HPS[10:8] :
High byte of the non-display period between the start of the horizontal sync (LLINE) signal and the first
display data. (POR = 000)
Low byte of the non-display period between the start of the horizontal sync (LLINE) signal and the first
display data. (POR = 00100000)
HPS[7:0] :
HPW[6:0] :
The horizontal sync pulse width (LLINE) in pixel clock. (POR = 0000111)
LPS[10:8] :
LPS[7:0] :
High byte of the horizontal sync pulse (LLINE) start location in pixel clock. (POR = 000)
Low byte of the horizontal sync pulse width (LLINE) in start. (POR = 00000000)
LPSPP[1:0] : The horizontal sync pulse subpixel start position (POR = 00)
Solomon Systech
Jan 2010
P 48/93
Rev 1.1
SSD1963
9.37 set_vert_period
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xB6
7
D/C
0
1
1
1
1
1
1
1
D7
1
0
VT7
0
VPS7
0
0
FPS7
D6
0
0
VT6
0
VPS6
VPW6
0
FPS6
D5
1
0
VT5
0
VPS5
VPW5
0
FPS5
D4
1
0
VT4
0
VPS4
VPW4
0
FPS4
D3
0
0
VT3
0
VPS3
VPW3
0
FPS3
D2
1
VT10
VT2
VPS10
VPS2
VPW2
FPS10
FPS2
D1
1
VT9
VT1
VPS9
VPS1
VPW1
FPS9
FPS1
D0
0
VT8
VT0
VPS8
VPS0
VPW0
FPS8
FPS0
Hex
B6
xx
xx
xx
xx
xx
xx
xx
Description
Set the vertical blanking interval between last scan line and next LFRAME pulse
VT[10:8] :
VT[7:0] :
High byte of the vertical total (display + non-display) period in lines (POR = 001)
Low byte of the vertical total (display + non-display) period in lines (POR = 11101111)
Vertical Total = (VT + 1) lines
VPS[10:8] :
High byte the non-display period in lines between the start of the frame and the first display data in line.
(POR = 000)
The non-display period in lines between the start of the frame and the first display data in line. (POR =
00000100)
Vertical Sync Pulse Start Position = VPS lines
VPS[7:0] :
VPW[6:0] :
Set the vertical sync pulse width (LFRAME) in lines. (POR = 000001)
Vertical Sync Pulse Width = (VPW + 1) lines
FPS[10:8] :
FPS[7:0] :
High byte of the vertical sync pulse (LFRAME) start location in lines. (POR = 000)
Low byte of the vertical sync pulse (LFRAME) start location in lines. (POR = 00000000)
Vertical Display Period Start Position = FPS lines
Timing refer to Figure 13-5.
9.38 get_vert_period
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xB7
7
D/C
0
1
1
1
1
1
1
1
D7
1
0
VT7
0
VPS7
0
0
FPS7
D6
0
0
VT6
0
VPS6
VPW6
0
FPS6
D5
1
0
VT5
0
VPS5
VPW5
0
FPS5
D4
1
0
VT4
0
VPS4
VPW4
0
FPS4
D3
0
0
VT3
0
VPS3
VPW3
0
FPS3
D2
1
VT10
VT2
VPS10
VPS2
VPW2
FPS10
FPS2
D1
1
VT9
VT1
VPS9
VPS1
VPW1
FPS9
FPS1
D0
1
VT8
VT0
VPS8
VPS0
VPW0
FPS8
FPS0
Hex
B7
xx
xx
xx
xx
xx
xx
xx
Description
Get the vertical blanking interval between last scan line and next LFRAME pulse
SSD1963
Rev 1.1
P 49/93
Jan 2010
Solomon Systech
VT[10:8] :
VT[7:0] :
High byte of the vertical total (display + non-display) period in lines (POR = 001)
Low byte of the vertical total (display + non-display) period in lines (POR = 01111111)
VPS[10:8] : High byte of the non-display period in lines between the start of the frame and the first display data in line.
(POR = 000)
VPS[7:0] : Low byte of the non-display period in lines between the start of the frame and the first display data in line.
(POR = 00000100)
VPW[6:0] : The vertical sync pulse width (LFRAME) in lines. (POR = 000001)
FPS[10:8] : High byte of the vertical sync pulse (LFRAME) start location in lines. (POR = 000)
FPS[7:0] : Low byte of the vertical sync pulse (LFRAME) start location in lines. (POR = 00000000)
9.39 set_gpio_conf
Command
Parameters
Command
Parameter 1
Parameter 2
0xB8
2
D/C
0
1
1
D7
1
A7
0
D6
0
A6
0
D5
1
A5
0
D4
1
A4
0
D3
1
A3
0
D2
0
A2
0
D1
0
A1
0
D0
0
A0
B0
Hex
B8
xx
xx
Description
Set the GPIOs configuration. If the GPIOs are not used for LCD, set the direction. Otherwise, they are toggled with
LCD signals by 0xC0 – 0xCF.
A[7] : GPIO3 configuration (POR = 0)
0
GPIO3 is controlled by host
1
GPIO3 is controlled by LCDC
A[6] : GPIO2 configuration (POR = 0)
0
GPIO2 is controlled by host
1
GPIO2 is controlled by LCDC
A[5] : GPIO1 configuration (POR = 0)
0
GPIO1 is controlled by host
1
GPIO1 is controlled by LCDC
A[4] : GPIO0 configuration (POR = 0)
0
GPIO0 is controlled by host
1
GPIO0 is controlled by LCDC
A[3] : GPIO3 direction (POR = 0)
0
GPIO3 is input
1
GPIO3 is output
A[2] : GPIO3 direction (POR = 0)
0
GPIO2 is input
1
GPIO2 is output
A[1] : GPIO1 direction (POR = 0)
0
GPIO1 is input
1
GPIO1 is output
A[0] : GPIO0 direction (POR = 0)
0
GPIO0 is input
1
GPIO0 is output
Solomon Systech
Jan 2010
P 50/93
Rev 1.1
SSD1963
B[0] : GPIO0 direction (POR = 0)
0
GPIO0 is used to control the panel power with enter_sleep_mode (0x10) or exit_sleep_mode (0x11).
1
GPIO0 is used as normal GPIO
9.40 get_gpio_conf
Command
Parameters
Command
Parameter 1
Parameter 2
0xB9
2
D/C
0
1
1
D7
1
A7
0
D6
0
A6
0
D5
1
A5
0
D4
1
A4
0
D3
1
A3
0
D2
0
A2
0
D1
0
A1
0
D0
1
A0
B0
Hex
B9
xx
xx
Description
Get the current GPIOs configuration
A[7] : GPIO3 configuration (POR = 0)
0
GPIO3 is controlled by host
1
GPIO3 is controlled by LCDC
A[6] : GPIO2 configuration (POR = 0)
0
GPIO2 is controlled by host
1
GPIO2 is controlled by LCDC
A[5] : GPIO1 configuration (POR = 0)
0
GPIO1 is controlled by host
1
GPIO1 is controlled by LCDC
A[4] : GPIO0 configuration (POR = 0)
0
GPIO0 is controlled by host
1
GPIO0 is controlled by LCDC
A[3] : GPIO3 direction (POR = 0)
0
GPIO3 is input
1
GPIO3 is output
A[2] : GPIO3 direction (POR = 0)
0
GPIO2 is input
1
GPIO2 is output
A[1] : GPIO1 direction (POR = 0)
0
GPIO1 is input
1
GPIO1 is output
A[0] : GPIO0 direction (POR = 0)
0
GPIO0 is input
1
GPIO0 is output
B[0] : GPIO0 direction (POR = 0)
0
GPIO0 is used to control the panel power with enter_sleep_mode (0x10) or exit_sleep_mode (0x11)
1
GPIO0 is used as normal GPIO
SSD1963
Rev 1.1
P 51/93
Jan 2010
Solomon Systech
9.41 set_gpio_value
Command
Parameters
Command
Parameter 1
0xBA
1
D/C
0
1
D7
1
0
D6
0
0
D5
1
0
D4
1
0
D3
1
A3
D2
0
A2
D1
1
A1
D0
0
A0
Hex
BA
xx
D5
1
0
D4
1
0
D3
1
A3
D2
0
A2
D1
1
A1
D0
1
A0
Hex
BB
xx
Description
Set GPIO value for GPIO configured as output
A[3] : GPIO3 value (POR = 0)
0
GPIO3 outputs 0
1
GPIO3 outputs 1
A[2] : GPIO2 value (POR = 0)
0
GPIO2 outputs 0
1
GPIO2 outputs 1
A[1] : GPIO1 value (POR = 0)
0
GPIO1 outputs 0
1
GPIO1 outputs 1
A[0] : GPIO0 value (POR = 0)
0
GPIO0 outputs 0
1
GPIO0 outputs 1
9.42 get_gpio_status
Command
Parameters
Command
Parameter 1
0xBB
1
D/C
0
1
D7
1
0
D6
0
0
Description
Read current GPIO status. If the individual GPIO was configured as input, the value is the status of the corresponding
pin. Otherwise, it is the programmed value.
A[3] : GPIO3 value (POR : depends on pad value)
0
GPIO3 is pulled low
1
GPIO3 is pulled high
A[2] : GPIO2 value (POR : depends on pad value)
0
GPIO2 is pulled low
1
GPIO2 is pulled high
A[1] : GPIO1 value (POR : depends on pad value)
0
GPIO1 is pulled low
1
GPIO1 is pulled high
A[0] : GPIO0 value (POR : depends on pad value)
0
GPIO0 is pulled low
1
GPIO0 is pulled high
Solomon Systech
Jan 2010
P 52/93
Rev 1.1
SSD1963
9.43 set_post_proc
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
0xBC
4
D/C
0
1
1
1
1
D7
1
A7
B7
C7
0
D6
0
A6
B6
C6
0
D5
1
A5
B5
C5
0
D4
1
A4
B4
C4
0
D3
1
A3
B3
C3
0
D2
1
A2
B2
C2
0
D1
0
A1
B1
C1
0
D0
0
A0
B0
C0
D0
Hex
BC
xx
xx
xx
xx
D4
1
A4
B4
C4
0
D3
1
A3
B3
C3
0
D2
1
A2
B2
C2
0
D1
0
A1
B1
C1
0
D0
1
A0
B0
C0
D0
Hex
BD
xx
xx
xx
xx
Description
Set the image post processor
A[7:0] : Set the contrast value (POR = 01000000)
B[7:0] : Set the brightness value (POR = 10000000)
C[7:0] : Set the saturation value (POR = 01000000)
D[0] : Post Processor Enable (POR = 0)
0
Disable the postprocessor
1
Enable the postprocessor
9.44 get_post_proc
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
0xBD
4
D/C
0
1
1
1
1
D7
1
A7
B7
C7
0
D6
0
A6
B6
C6
0
D5
1
A5
B5
C5
0
Description
Get the image post processor
A[7:0] : Get the contrast value (POR = 01000000)
B[7:0] : Get the brightness value (POR = 10000000)
C[7:0] : Get the saturation value (POR = 01000000)
D[0] : Post Processor Enable (POR = 0)
0
Disable the postprocessor
1
Enable the postprocessor
SSD1963
Rev 1.1
P 53/93
Jan 2010
Solomon Systech
9.45 set_pwm_conf
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
0xBE
6
D/C
0
1
1
1
1
1
1
D7
D6
D5
D4
D3
D2
D1
D0
1
0
1
1
1
1
1
0
PWMF7 PWMF6 PWMF5 PWMF4 PWMF3 PWMF2 PWMF1 PWMF0
PWM7 PWM6 PWM5 PWM4 PWM3 PWM2 PWM1 PWM0
0
0
0
0
C3
0
0
C0
D7
D6
D5
D4
D3
D2
D1
D0
E7
E6
E5
E4
E3
E2
E1
E0
0
0
0
0
F3
F2
F1
F0
Hex
BE
xx
xx
xx
xx
xx
xx
Description
Set the PWM configuration
PWMF[7:0] : Set the PWM frequency in system clock (POR = 00000000)
PWM signal frequency = PLL clock / (256 * PWMF[7:0]) / 256
PWM[7:0] : Set the PWM duty cycle (POR = 00000000)
PWM duty cycle = PWM[7:0] / 256 for DBC disable (0xD0] A0 = 0
If DBC enable (0xD0] A0 = 1, these parameter will be ignored
Note : PWM always 0 if PWM[7:0] = 00h
Figure 9-19: PWM signal
Period = 1/ PWM Freq
PWM
PWM[7:0]/256 * Period
C[3] : PWM configuration (POR = 0)
0
PWM controlled by host
1
PWM controlled by DBC
C[0] : PWM enable (POR = 0)
0
PWM disable
1
PWM enable
D[7:0] : DBC manual brightness (POR = 00000000)
Set the manual brightness level. When Manual Brightness Mode (0xD0) A[6] is enabled, the final DBC duty cycle
output will be multiplied by this value / 255.
PWM duty cycle = DBC output * D[7:0] / 255
00
Dimmest
FF
brightest
E[7:0] : DBC minimum brightness (POR = 00000000)
Set the minimum brightness level. WhenManual Brightness Mode (0xD0) A[6] is enabled, DBC duty cycle output will
be limited by this value. This will prevent from backlight being too dark or off.
00
Dimmest
FF
Brightest
Solomon Systech
Jan 2010
P 54/93
Rev 1.1
SSD1963
F[3:0] : Brightness prescaler (POR = 0000)
Set the brightness prescaler to control how gradually the manual brightness is changed between different levels. There is
a filter will undergo a number of iterations before the manual brightness saturated. This parameter is valid when
Transition Effect enable (0xD0) A5 = 1
The iteration ration = system frequency / Divcode / 32768
F[3:0]
Divcode
0000
off
0001
1
0010
2
0011
3
0100
4
0101
6
0110
8
0111
12
1000
16
1001
24
1010
32
1011
48
1100
64
1101
96
1110
128
1111
192
9.46 get_pwm_conf
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xBF
7
D/C
0
1
1
1
1
1
1
1
D7
1
PWMF7
PWM7
0
D7
E7
0
G7
D6
0
PWMF6
PWM6
0
D6
E6
0
G6
D5
1
PWMF5
PWM5
0
D5
E5
0
G5
D4
1
PWMF4
PWM4
0
D4
E4
0
G4
D3
1
PWMF3
PWM3
C3
D3
E3
F3
G3
D2
1
PWMF2
PWM2
0
D2
E2
F2
G2
D1
1
PWMF1
PWM1
0
D1
E1
F1
G1
D0
1
PWMF0
PWM0
C0
D0
E0
F0
G0
Hex
BF
xx
xx
xx
xx
xx
xx
xx
Description
Get the PWM configuration
PWMF[7:0] : Get the PWM frequency in system clock (POR = 00000000)
PWM[7:0] : Get the PWM duty cycle (POR = 00000000)
C[3] : PWM configuration (POR = 0)
0
PWM controlled by host
1
PWM controlled by DBC
C[0] : PWM enable (POR = 0)
0
PWM disable
1
PWM enable
D[7:0] : DBC manual brightness (POR = 00000000)
Get the brightness level
00
Dimmest
FF
brightest
SSD1963
Rev 1.1
P 55/93
Jan 2010
Solomon Systech
E[7:0] : DBC minimum brightness (POR = 00000000)
Get the minimum brightness level.
00
Dimmest
FF
Brightest
F[3:0] : Brightness prescaler (POR = 0000)
Get the brightness prescaler
G[7:0] : Dynamic backlight duty cycle : Get the current PWM duty cycle controlled by PWM (POR = 00000000)
Solomon Systech
Jan 2010
P 56/93
Rev 1.1
SSD1963
9.47 set_lcd_gen0
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC0
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF07
0
GR07
F7
GP07
D6
1
0
0
GF06
0
GR06
F6
GP06
D5
0
0
0
GF05
0
GR05
F5
GP05
D4
0
0
0
GF04
0
GR04
F4
GP04
D3
0
0
0
GF03
0
GR03
F3
GP03
D2
0
0
GF010
GF02
GR010
GR02
GP010
GP02
D1
0
0
GF09
GF01
GR09
GR01
GP09
GP01
D0
0
0
GF08
GF00
GR08
GR00
GP08
GP00
Hex
C0
xx
xx
xx
xx
xx
xx
xx
Description
Set the rise, fall, period and toggling properties of LCD signal generator 0
A[7] : Reset LCD generator 0 at every frame start
0
The generator 0 will not reset in the starting point of a frame
1
The generator 0 will reset in the starting point of a frame
GF0[10:8] : The highest 3 bits of the generator 0 falling position (POR = 000)
GF0[7:0] : The lower byte of the generator 0 falling position (POR = 00000001)
GR0[10:8] : The highest 3 bits of the generator 0 rising position (POR = 000)
GR0[7:0] : The lower byte of the generator 0 rising position (POR = 00000000)
F[7] : Force the generator 0 output to 0 in non-display period
0
generator 0 is normal
1
generator 0 output is forced to 0 in non-display period
F[6:5] : Force the generator 0 output to 0 in odd or even lines
00
generator 0 is normal in both odd and even lines
01
generator 0 output is force to 0 in odd lines
10
generator 0 output is force to 0 in even lines
11
generator 0 is normal in both odd and even line
F[4:3] : Generator 0 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP0[10:8] : The highest 3 bits of the generator 0 period (POR = 100)
GP0[7:0] : The lower byte of the generator 0 period (POR = 00000000)
SSD1963
Rev 1.1
P 57/93
Jan 2010
Solomon Systech
9.48 get_lcd_gen0
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC1
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF07
0
GR07
F7
GP07
D6
1
0
0
GF06
0
GR06
F6
GP06
D5
0
0
0
GF05
0
GR05
F5
GP05
D4
0
0
0
GF04
0
GR04
F4
GP04
D3
0
0
0
GF03
0
GR03
F3
GP03
D2
0
0
GF010
GF02
GR010
GR02
GP010
GP02
D1
0
0
GF09
GF01
GR09
GR01
GP09
GP01
D0
1
0
GF08
GF00
GR08
GR00
GP08
GP00
Hex
C1
xx
xx
xx
xx
xx
xx
xx
Description
Get the rise, fall, period and toggling properties of LCD signal generator 0
A[7] : Reset LCD generator 0 at every frame start
0
The generator 0 will not reset in the starting point of a frame
1
The generator 0 will reset in the starting point of a frame
GF0[10:8] : The highest 3 bits of the generator 0 falling position (POR = 000)
GF0[7:0] : The lower byte of the generator 0 falling position (POR = 00000001)
GR0[10:8] : The highest 3 bits of the generator 0 rising position (POR = 000)
GR0[7:0] : The lower byte of the generator 0 rising position (POR = 00000000)
F[7] : Force the generator 0 output to 0 in non-display period
0
generator 0 is normal
1
generator 0 output is forced to 0 in non-display period
F[6:5] : Force the generator 0 output to 0 in odd or even lines
00
generator 0 is normal in both odd and even lines
01
generator 0 output is force to 0 in odd lines
10
generator 0 output is force to 0 in even lines
11
generator 0 is normal in both odd and even line
F[4:3] : Generator 0 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP0[10:8] : The highest 3 bits of the generator 0 period (POR = 100)
GP0[7:0] : The lower byte of the generator 0 period (POR = 00000000)
Solomon Systech
Jan 2010
P 58/93
Rev 1.1
SSD1963
9.49 set_lcd_gen1
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC2
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF17
0
GR17
F7
GP17
D6
1
0
0
GF16
0
GR16
F6
GP16
D5
0
0
0
GF15
0
GR15
F5
GP15
D4
0
0
0
GF14
0
GR14
F4
GP14
D3
0
0
0
GF13
0
GR13
F3
GP13
D2
0
0
GF110
GF12
GR110
GR12
GP110
GP12
D1
1
0
GF19
GF11
GR19
GR11
GP19
GP11
D0
0
0
GF18
GF10
GR18
GR10
GP18
GP10
Hex
C2
xx
xx
xx
xx
xx
xx
xx
Description
Set the rise, fall, period and toggling properties of LCD signal generator 1
A[7] : Reset LCD generator 1 at every frame start
0
The generator 1 will not reset in the starting point of a frame
1
The generator 1 will reset in the starting point of a frame
GF1[10:8] : The highest 3 bits of the generator 1 falling position (POR = 000)
GF1[7:0] : The lower byte of the generator 1 falling position (POR = 00000001)
GR1[10:8] : The highest 3 bits of the generator 1 rising position (POR = 000)
GR1[7:0] : The lower byte of the generator 1 rising position (POR = 00000000)
F[7] : Force the generator 1 output to 0 in non-display period
0
generator 1 is normal
1
generator 1 output is forced to 0 in non-display period
F[6:5] : Force the generator 1 output to 0 in odd or even lines
00
generator 1 is normal in both odd and even lines
01
generator 1 output is force to 0 in odd lines
10
generator 1 output is force to 0 in even lines
11
generator 1 is normal in both odd and even line
F[4:3] : Generator 1 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP1[10:8] : The highest 3 bits of the generator 1 period (POR = 100)
GP1[7:0] : The lower byte of the generator 1 period (POR = 00000000)
SSD1963
Rev 1.1
P 59/93
Jan 2010
Solomon Systech
9.50 get_lcd_gen1
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC3
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF17
0
GR17
F7
GP17
D6
1
0
0
GF16
0
GR16
F6
GP16
D5
0
0
0
GF15
0
GR15
F5
GP15
D4
0
0
0
GF14
0
GR14
F4
GP14
D3
0
0
0
GF13
0
GR13
F3
GP13
D2
0
0
GF110
GF12
GR110
GR12
GP110
GP12
D1
1
0
GF19
GF11
GR19
GR11
GP19
GP11
D0
1
0
GF18
GF10
GR18
GR10
GP18
GP10
Hex
C3
xx
xx
xx
xx
xx
xx
xx
Description
Get the rise, fall, period and toggling properties of LCD signal generator 1
A[7] : Reset LCD generator 1 at every frame start
0
The generator 1 will not reset in the starting point of a frame
1
The generator 1 will reset in the starting point of a frame
GF1[10:8] : The highest 3 bits of the generator 1 falling position (POR = 000)
GF1[7:0] : The lower byte of the generator 1 falling position (POR = 00000001)
GR1[10:8] : The highest 3 bits of the generator 1 rising position (POR = 000)
GR1[7:0] : The lower byte of the generator 1 rising position (POR = 00000000)
F[7] : Force the generator 1 output to 0 in non-display period
0
generator 1 is normal
1
generator 1 output is forced to 0 in non-display period
F[6:5] : Force the generator 1 output to 0 in odd or even lines
00
generator 1 is normal in both odd and even lines
01
generator 1 output is force to 0 in odd lines
10
generator 1 output is force to 0 in even lines
11
generator 1 is normal in both odd and even line
F[4:3] : Generator 1 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP1[10:8] : The highest 3 bits of the generator 1 period (POR = 100)
GP1[7:0] : The lower byte of the generator 1 period (POR = 00000000)
Solomon Systech
Jan 2010
P 60/93
Rev 1.1
SSD1963
9.51 set_lcd_gen2
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC4
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF27
0
GR27
F7
GP27
D6
1
0
0
GF26
0
GR26
F6
GP26
D5
0
0
0
GF25
0
GR25
F5
GP25
D4
0
0
0
GF24
0
GR24
F4
GP24
D3
0
0
0
GF23
0
GR23
F3
GP23
D2
1
0
GF210
GF22
GR210
GR22
GP210
GP22
D1
0
0
GF29
GF21
GR29
GR21
GP29
GP21
D0
0
0
GF28
GF20
GR28
GR20
GP28
GP20
Hex
C4
xx
xx
xx
xx
xx
xx
xx
Description
Set the rise, fall, period and toggling properties of LCD signal generator 2
A[7] : Reset LCD generator 2 at every frame start
0
The generator 2 will not reset in the starting point of a frame
1
The generator 2 will reset in the starting point of a frame
GF2[10:8] : The highest 3 bits of the generator 2 falling position (POR = 000)
GF2[7:0] : The lower byte of the generator 2 falling position (POR = 00000001)
GR2[10:8] : The highest 3 bits of the generator 2 rising position (POR = 000)
GR2[7:0] : The lower byte of the generator 2 rising position (POR = 00000000)
F[7] : Force the generator 2 output to 0 in non-display period
0
generator 2 is normal
1
generator 2 output is forced to 0 in non-display period
F[6:5] : Force the generator 2 output to 0 in odd or even lines
00
generator 2 is normal in both odd and even lines
01
generator 2 output is force to 0 in odd lines
10
generator 2 output is force to 0 in even lines
11
generator 2 is normal in both odd and even line
F[4:3] : Generator 2 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP2[10:8] : The highest 3 bits of the generator 2 period (POR = 100)
GP2[7:0] : The lower byte of the generator 2 period (POR = 00000000)
SSD1963
Rev 1.1
P 61/93
Jan 2010
Solomon Systech
9.52 get_lcd_gen2
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC5
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF27
0
GR27
F7
GP27
D6
1
0
0
GF26
0
GR26
F6
GP26
D5
0
0
0
GF25
0
GR25
F5
GP25
D4
0
0
0
GF24
0
GR24
F4
GP24
D3
0
0
0
GF23
0
GR23
F3
GP23
D2
1
0
GF210
GF22
GR210
GR22
GP210
GP22
D1
0
0
GF29
GF21
GR29
GR21
GP29
GP21
D0
1
0
GF28
GF20
GR28
GR20
GP28
GP20
Hex
C5
xx
xx
xx
xx
xx
xx
xx
Description
Get the rise, fall, period and toggling properties of LCD signal generator 2
A[7] : Reset LCD generator 2 at every frame start
0
The generator 2 will not reset in the starting point of a frame
1
The generator 2 will reset in the starting point of a frame
GF2[10:8] : The highest 3 bits of the generator 2 falling position (POR = 000)
GF2[7:0] : The lower byte of the generator 2 falling position (POR = 00000001)
GR2[10:8] : The highest 3 bits of the generator 2 rising position (POR = 000)
GR2[7:0] : The lower byte of the generator 2 rising position (POR = 00000000)
F[7] : Force the generator 2 output to 0 in non-display period
0
generator 2 is normal
1
generator 2 output is forced to 0 in non-display period
F[6:5] : Force the generator 2 output to 0 in odd or even lines
00
generator 2 is normal in both odd and even lines
01
generator 2 output is force to 0 in odd lines
10
generator 2 output is force to 0 in even lines
11
generator 2 is normal in both odd and even line
F[4:3] : Generator 2 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP2[10:8] : The highest 3 bits of the generator 2 period (POR = 100)
GP2[7:0] : The lower byte of the generator 2 period (POR = 00000000)
Solomon Systech
Jan 2010
P 62/93
Rev 1.1
SSD1963
9.53 set_lcd_gen3
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC6
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF37
0
GR37
F7
GP37
D6
1
0
0
GF36
0
GR36
F6
GP36
D5
0
0
0
GF35
0
GR35
F5
GP35
D4
0
0
0
GF34
0
GR34
F4
GP34
D3
0
0
0
GF33
0
GR33
F3
GP33
D2
1
0
GF310
GF32
GR310
GR32
GP310
GP32
D1
1
0
GF39
GF31
GR39
GR31
GP39
GP31
D0
0
0
GF38
GF30
GR38
GR30
GP38
GP30
Hex
C6
xx
xx
xx
xx
xx
xx
xx
Description
Set the rise, fall, period and toggling properties of LCD signal generator 3
A[7] : Reset LCD generator 3 at every frame start
0
The generator 3 will not reset in the starting point of a frame
1
The generator 3 will reset in the starting point of a frame
GF3[10:8] : The highest 3 bits of the generator 3 falling position (POR = 000)
GF3[7:0] : The lower byte of the generator 3 falling position (POR = 00000001)
GR3[10:8] : The highest 3 bits of the generator 3 rising position (POR = 000)
GR3[7:0] : The lower byte of the generator 3 rising position (POR = 00000000)
F[7] : Force the generator 3 output to 0 in non-display period
0
generator 3 is normal
1
generator 3 output is forced to 0 in non-display period
F[6:5] : Force the generator 3 output to 0 in odd or even lines
00
generator 3 is normal in both odd and even lines
01
generator 3 output is force to 0 in odd lines
10
generator 3 output is force to 0 in even lines
11
generator 3 is normal in both odd and even line
F[4:3] : Generator 3 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP3[10:8] : The highest 3 bits of the generator 3 period (POR = 100)
GP3[7:0] : The lower byte of the generator 3 period (POR = 00000000)
SSD1963
Rev 1.1
P 63/93
Jan 2010
Solomon Systech
9.54 get_lcd_gen3
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
0xC7
7
D/C
0
1
1
1
1
1
1
1
D7
1
A7
0
GF37
0
GR37
F7
GP37
D6
1
0
0
GF36
0
GR36
F6
GP36
D5
0
0
0
GF35
0
GR35
F5
GP35
D4
0
0
0
GF34
0
GR34
F4
GP34
D3
0
0
0
GF33
0
GR33
F3
GP33
D2
1
0
GF310
GF32
GR310
GR32
GP310
GP32
D1
1
0
GF39
GF31
GR39
GR31
GP39
GP31
D0
1
0
GF38
GF30
GR38
GR30
GP38
GP30
Hex
C7
xx
xx
xx
xx
xx
xx
xx
Description
Get the rise, fall, period and toggling properties of LCD signal generator 3
A[7] : Reset LCD generator 3 at every frame start
0
The generator 3 will not reset in the starting point of a frame
1
The generator 3 will reset in the starting point of a frame
GF3[10:8] : The highest 3 bits of the generator 3 falling position (POR = 000)
GF3[7:0] : The lower byte of the generator 3 falling position (POR = 00000001)
GR3[10:8] : The highest 3 bits of the generator 3 rising position (POR = 000)
GR3[7:0] : The lower byte of the generator 3 rising position (POR = 00000000)
F[7] : Force the generator 3 output to 0 in non-display period
0
generator 3 is normal
1
generator 3 output is forced to 0 in non-display period
F[6:5] : Force the generator 3 output to 0 in odd or even lines
00
generator 3 is normal in both odd and even lines
01
generator 3 output is force to 0 in odd lines
10
generator 3 output is force to 0 in even lines
11
generator 3 is normal in both odd and even line
F[4:3] : Generator 3 toggle mode
00
Disable
01
Toggle by pixel clock (LSHIFT)
10
Toggle by Line (LLINE)
11
Toggle by Frame (LFRAME)
GP3[10:8] : The highest 3 bits of the generator 3 period (POR = 100)
GP3[7:0] : The lower byte of the generator 3 period (POR = 00000000)
Solomon Systech
Jan 2010
P 64/93
Rev 1.1
SSD1963
9.55 set_gpio0_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xC8
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
0
A2
B2
D1
0
A1
B1
D0
0
A0
B0
Hex
C8
xx
xx
Description
Set the GPIO0 with respect to the LCD signal generators using ROP operation. No effect if the GPIO0 is configured as
general GPIO.
A[6:5] : Source 1 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[3:2] : Source 2 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO0 (POR = 00000000)
Please refer to the Application note for the ROP operation
9.56 get_gpio0_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xC9
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
0
A2
B2
D1
0
A1
B1
D0
1
A0
B0
Hex
C9
xx
xx
Description
Get the GPIO0 properties with respect to the LCD signal generators.
A[6:5] : Source 1 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
SSD1963
Rev 1.1
P 65/93
Jan 2010
Solomon Systech
A[3:2] : Source 2 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO0 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO0 (POR = 00000000)
Please refer to the Application note for ROP operation
9.57 set_gpio1_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCA
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
0
A2
B2
D1
1
A1
B1
D0
0
A0
B0
Hex
CA
xx
xx
Description
Set the GPIO1 with respect to the LCD signal generators using ROP operation. No effect if the GPIO1 is configured as
general GPIO.
A[6:5] : Source 1 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[3:2] : Source 2 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO1 (POR = 00000000)
Please refer to the Application note for the ROP operation
Solomon Systech
Jan 2010
P 66/93
Rev 1.1
SSD1963
9.58 get_gpio1_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCB
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
0
A2
B2
D1
1
A1
B1
D0
1
A0
B0
Hex
CB
xx
xx
D1
0
A1
B1
D0
0
A0
B0
Hex
CC
xx
xx
Description
Get the GPIO1 properties with respect to the LCD signal generators.
A[6:5] : Source 1 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[3:2] : Source 2 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO1 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO1 (POR = 00000000)
Please refer to the Application note for the ROP operation
9.59 set_gpio2_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCC
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
1
A2
B2
Description
Set the GPIO2 with respect to the LCD signal generators using ROP operation. No effect if the GPIO2 is configured as
general GPIO.
A[6:5] : Source 1 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
SSD1963
Rev 1.1
P 67/93
Jan 2010
Solomon Systech
A[3:2] : Source 2 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO2 (POR = 00000000)
Please refer to the Application note for the ROP operation
9.60 get_gpio2_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCD
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
1
A2
B2
D1
0
A1
B1
D0
1
A0
B0
Hex
CD
xx
xx
Description
Get the GPIO2 properties with respect to the LCD signal generators.
A[6:5] : Source 1 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[3:2] : Source 2 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO2 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO2 (POR = 00000000)
Please refer to the Application note for the ROP operation
Solomon Systech
Jan 2010
P 68/93
Rev 1.1
SSD1963
9.61 set_gpio3_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCE
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
1
A2
B2
D1
1
A1
B1
D0
0
A0
B0
Hex
CE
xx
xx
Description
Set the GPIO3 with respect to the LCD signal generators using ROP operation. No effect if the GPIO3 is configured as
general GPIO.
A[6:5] : Source 1 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[3:2] : Source 2 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO3 (POR = 00000000)
Please refer to the Application note for the ROP operation
9.62 get_gpio3_rop
Command
Parameters
Command
Parameter 1
Parameter 2
0xCF
2
D/C
0
1
1
D7
1
0
B7
D6
1
A6
B6
D5
0
A5
B5
D4
0
0
B4
D3
1
A3
B3
D2
1
A2
B2
D1
1
A1
B1
D0
1
A0
B0
Hex
CF
xx
xx
Description
Get the GPIO3 properties with respect to the LCD signal generators.
A[6:5] : Source 1 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
SSD1963
Rev 1.1
P 69/93
Jan 2010
Solomon Systech
A[3:2] : Source 2 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
A[1:0] : Source 3 for GPIO3 when controlled by LCDC (POR = 00)
00
Generator 0
01
Generator 1
10
Generator 2
11
Generator 3
B[7:0] : ROP operation to mux the source 1, 2 and 3 for GPIO3 (POR = 00000000)
Please refer to the Application note for the ROP operation
9.63 set_dbc_conf
Command
Parameters
Command
Parameter 1
0xD0
1
D/C
0
1
D7
1
0
D6
1
A6
D5
0
A5
D4
1
0
D3
0
A3
D2
0
A2
D1
0
0
D0
0
A0
Hex
D0
xx
Description
Set the Dynamic Backlight Control configuration.
A[6] : DBC Manual Brightness enable (POR = 1)
0
Enable
1
Disable
A[5] : Transition effect (POR = 0)
0
Transition effect disable
1
Transition effect enable
Transition effect is used to remove visible backlight flickering. If rapid brightness change is required, it is recommended
to enable this bit.
A[3:2] : Energy saving selection for DBC (POR = 00)
00
DBC is disable
01
Conservative mode
10
Normal mode
11
Aggressive mode
A[0] : Master enable of DBC (POR = 0)
0
DBC disable
1
DBC enable
Solomon Systech
Jan 2010
P 70/93
Rev 1.1
SSD1963
The hardware pin, PWM is the output signal from SSD1963 to the system backlight driver. So it should configure PWM
module before enable DBC.
WRITE COMMAND “0xBE”
WRITE DATA “0x0E” (set PWM frequency)
WRITE DATA “0xFF” (dummy value if DBC is used)
WRITE DATA “0x09” (enable PWM controlled by DBC)
WRITE DATA “0xFF”
WRITE DATA “0x00”
WRITE DATA “0x00”
WRITE COMMAND “0xD4”
WRITE DATA …..
(Define the threshold value)
WRITE COMMAND “0xD0”
WRITE DATA “0x0D” (Enable DBC with Aggressive mode)
9.64 get_dbc_conf
Command
Parameters
Command
Parameter 1
0xD1
1
D/C
0
1
D7
1
0
D6
1
A6
D5
0
A5
D4
1
0
D3
0
A3
D2
0
A2
D1
0
1
D0
1
A0
Hex
D1
xx
Description
Get the current dynamic back light configuration.
A[6] : DBC Manual Brightness enable (POR = 1)
0
Enable
1
Disable
A[5] : Transition effect (POR = 0)
0
Transition effect disable
1
Transition effect enable
A[3:2] : Energy saving selection for DBC (POR = 00)
00
DBC is disable
01
Conservative mode
10
Normal mode
11
Aggressive mode
A[0] : Master enable DBC (POR = 0)
0
DBC disable
1
DBC enable
SSD1963
Rev 1.1
P 71/93
Jan 2010
Solomon Systech
9.65 set_dbc_th
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
Parameter 8
Parameter 9
0xD4
9
D/C
D7
D6
D5
D4
D3
D2
D1
D0
Hex
0
1
1
0
1
0
1
1
0
0
0
0
0
0
0
0
D4
0
DBC_TH116
xx
1
DBC_TH115 DBC_TH114 DBC_TH113 DBC_TH112 DBC_TH111 DBC_TH110 DBC_TH19 DBC_TH18
xx
1
DBC_TH17
xx
1
0
DBC_TH16 DBC_TH15 DBC_TH14 DBC_TH13 DBC_TH12 DBC_TH11 DBC_TH10
DBC_TH216
xx
1
DBC_TH215 DBC_TH214 DBC_TH213 DBC_TH212 DBC_TH211 DBC_TH210 DBC_TH29 DBC_TH28
0
0
0
0
0
0
xx
1
DBC_TH27
xx
1
0
DBC_TH26 DBC_TH25 DBC_TH24 DBC_TH23 DBC_TH22 DBC_TH21 DBC_TH20
0
0
0
0
0
0
DBC_TH316
xx
1
DBC_TH315 DBC_TH314 DBC_TH313 DBC_TH312 DBC_TH311 DBC_TH310 DBC_TH39 DBC_TH38
xx
1
DBC_TH37
xx
DBC_TH36 DBC_TH35 DBC_TH34 DBC_TH33 DBC_TH32 DBC_TH31 DBC_TH30
Description
Set the threshold for each level of power saving.
DBC_TH1[16] : High byte of the threshold setting for the Conservative mode of DBC. (POR = 0)
DBC_TH1[15:8] : 2nd byte of the threshold setting for the Conservative mode of DBC. (POR = 00000000)
DBC_TH1[7:0] : Low byte of the threshold setting for the Conservative mode of DBC. (POR = 00000000)
TH1 = display width * display height * 3 * 0.1 /16
DBC_TH2[16] : High byte of the threshold setting for the Normal mode of DBC. (POR = 0)
DBC_TH2[15:8] : 2nd byte of the threshold setting for the Normal mode of DBC. (POR = 00000000)
DBC_TH2[7:0] : Low byte of the threshold setting for the Normal mode of DBC. (POR = 00000000)
TH2 = display width * display height * 3 * 0.25 /16
DBC_TH3[16] : High byte of the threshold setting for the Aggressive mode of DBC. (POR = 0)
DBC_TH3[15:8] : 2nd byte of the threshold setting for the Aggressive mode of DBC. (POR = 00000000)
DBC_TH3[7:0] : Low byte of the threshold setting for the Aggressive mode of DBC. (POR = 00000000)
TH3 = display width * display height * 3 * 0.6 /16
Solomon Systech
Jan 2010
P 72/93
Rev 1.1
SSD1963
9.66 get_dbc_th
Command
Parameters
0xD5
9
D/C
D7
0
1
1
0
Command
Parameter 1
Parameter 2
Parameter 3
Parameter 4
Parameter 5
Parameter 6
Parameter 7
Parameter 8
Parameter 9
D0
Hex
0
1
D5
0
DBC_TH116
xx
1
DBC_TH115 DBC_TH114 DBC_TH113 DBC_TH112 DBC_TH111 DBC_TH110 DBC_TH19 DBC_TH18
xx
1
DBC_TH17 DBC_TH16 DBC_TH15 DBC_TH14 DBC_TH13 DBC_TH12 DBC_TH11 DBC_TH10
xx
1
D6
0
D5
D4
D3
D2
D1
1
0
1
0
1
0
0
0
0
0
DBC_TH216
xx
1
DBC_TH215 DBC_TH214 DBC_TH213 DBC_TH212 DBC_TH211 DBC_TH210 DBC_TH29 DBC_TH28
xx
1
DBC_TH27 DBC_TH26 DBC_TH25 DBC_TH24 DBC_TH23 DBC_TH22 DBC_TH21 DBC_TH20
xx
1
0
0
0
0
0
0
0
0
0
0
0
0
0
DBC_TH316
xx
1
DBC_TH315 DBC_TH314 DBC_TH313 DBC_TH312 DBC_TH311 DBC_TH310 DBC_TH39 DBC_TH38
xx
1
DBC_TH37 DBC_TH36 DBC_TH35 DBC_TH34 DBC_TH33 DBC_TH32 DBC_TH31 DBC_TH30
xx
Description
Get the threshold for each level of power saving.
DBC_TH1[16] : High byte of the threshold setting for the Conservative mode of DBC. (POR = 0)
DBC_TH1[15:8] : 2nd byte of the threshold setting for the Conservative mode of DBC. (POR = 00000000)
DBC_TH1[7:0] : Low byte of the threshold setting for the Conservative mode of DBC. (POR = 00000000)
DBC_TH2[16] : High byte of the threshold setting for the Normal mode of DBC. (POR = 0)
DBC_TH2[15:8] : 2nd byte of the threshold setting for the Normal mode of DBC. (POR = 00000000)
DBC_TH2[7:0] : Low byte of the threshold setting for the Normal mode of DBC. (POR = 00000000)
DBC_TH3[16] : High byte of the threshold setting for the Aggressive mode of DBC. (POR = 0)
DBC_TH3[15:8] : 2nd byte of the threshold setting for the Aggressive mode of DBC. (POR = 00000000)
DBC_TH3[7:0] : Low byte of the threshold setting for the Aggressive mode of DBC. (POR = 00000000)
9.67 set_pll
Command
Parameters
Command
Parameter 1
0xE0
1
D/C
0
1
D7
1
0
D6
1
0
D5
1
0
D4
0
0
D3
0
0
D2
0
0
D1
0
A1
D0
0
A0
Hex
E0
xx
Description
Start the PLL. Before the start, the system was operated with the crystal oscillator or clock input.
A[1] : Lock PLL (POR = 0)
After PLL enabled for 100us, can start to lock PLL
0
Use reference clock as system clock
1
Use PLL output as system clock
A[0] : Enable PLL (POR = 0)
0
Disable PLL
1
Enable PLL
SSD1963
Rev 1.1
P 73/93
Jan 2010
Solomon Systech
Before enabling PLL, the PLL setting (“0xE2”) have to be configured first. After PLL enabled for 100us, can start to
lock PLL. SSD1963 needed to switch to PLL output as system clock after PLL is locked. The following is the program
sequence.
WRITE COMMAND “0xE0”
WRITE DATA “0x01”
Wait 100us to let the PLL stable
WRITE COMMAND “0xE0”
WRITE DATA “0x03”
WRITE COMMAND “0x01”
* Note : SSD1963 is operating under reference clock before PLL is locked, registers cannot be set faster than half of the
reference clock frequency. For instance, SSD1963 with a 10MHz reference clock is not allowed to be programmed
higher than 5M words/s.
9.68 set_pll_mn
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
0xE2
3
D/C
0
1
1
1
D7
1
M7
0
0
D6
1
M6
0
0
D5
1
M5
0
0
D4
0
M4
0
0
D3
0
M3
N3
0
D2
0
M2
N2
C2
D1
1
M1
N1
0
D0
0
M0
N0
0
Hex
E2
xx
xx
xx
Description
Set the MN of PLL
M[7:0] : Multiplier (M) of PLL. (POR = 00101101)
N[3:0] : Divider (N) of PLL. (POR = 0011)
C[2] : Effectuate MN value (POR = 0)
0
Ignore the multiplier (N) and divider (N) values
1
Effectuate the multiplier and divider value
VCO = Reference input clock x (M + 1)
PLL frequency = VCO / (N + 1)
* Note : 250MHz < VCO < 800MHz
For a 10MHz reference clock to obtain 100MHz PLL frequency, user cannot program M = 19 and N = 1. The setting in
this situation is setting M=29 and N=2, where 10 x 30 / 3 = 100MHz.
WRITE COMMAND “0xE2”
WRITE DATA “0x1D” (M=29)
WRITE DATA “0x02” (N=2)
WRITE DATA “0x54” (Dummy Byte)
Solomon Systech
Jan 2010
P 74/93
Rev 1.1
SSD1963
9.69 get_pll_mn
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
0xE3
3
D/C
0
1
1
1
D7
1
M7
0
0
D6
1
M6
0
0
D5
1
M5
0
0
D4
0
M4
0
0
D3
0
M3
N3
0
D2
0
M2
N2
C2
D1
1
M1
N1
0
D0
1
M0
N0
0
Hex
E3
xx
xx
xx
Description
Get the MN setting of PLL
M[7:0] : Multiplier (M) of PLL. (POR = 00101101)
N[3:0] : Divider (N) of PLL. (POR = 0011)
C[2] : Effectuate MN value (POR = 0)
0
Ignore the multiplier (M) and divider (N) values.
1
Effectuate the multiplier and divider value
9.70 get_pll_status
Command
Parameters
Command
Parameter 1
0xE4
1
D/C
0
1
D7
1
0
D6
1
0
D5
1
0
D4
0
0
D3
0
0
D2
1
A2
D1
0
0
D0
0
0
Hex
E4
xx
D6
1
D5
1
D4
0
D3
0
D2
1
D1
0
D0
1
Hex
E5
Description
Get the PLL status
A[2] : PLL Lock
0
Not locked
1
Locked
9.71 set_deep_sleep
Command
Parameters
Command
0xE5
None
D/C
0
D7
1
Description
Set deep sleep mode. PLL would be stopped.
It needs to issue 2 dummy read to exit Deep Sleep mode.
SSD1963
Rev 1.1
P 75/93
Jan 2010
Solomon Systech
9.72 set_lshift_freq
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
0xE6
3
D/C
D7
D6
D5
D4
0
1
1
1
0
1
0
0
0
0
D3
D2
D1
D0
Hex
0
1
1
0
E6
LCDC_FPR19 LCDC_FPR18 LCDC_FPR17 LCDC_FPR16
xx
1
LCDC_FPR15 LCDC_FPR14 LCDC_FPR13 LCDC_FPR12 LCDC_FPR11 LCDC_FPR10 LCDC_FPR9 LCDC_FPR8
xx
1
LCDC_FPR7 LCDC_FPR6 LCDC_FPR 5 LCDC_FPR4 LCDC_FPR 3 LCDC_FPR2 LCDC_FPR1 LCDC_FPR0
xx
Description
Set the LSHIFT (pixel clock) frequency
LCDC_FPR[19:16] : The highest 4 bits for the pixel clock frequency settings. (POR = 0111)
LCDC_FPR[15:8] : The higher byte for the pixel clock frequency settings. (POR = 11111111)
LCDC_FPR[7:0] : The low byte for the pixel clock frequency settings. (POR = 11111111)
For parallel LCD interface:
Configure the pixel clock to PLL freq x ((LCDC_FPR + 1) / 220)
To obtain PCLK = 5.3MHz with PLL Frequency = 100MHz,
5.3MHz = 100MHz * ( LCDC_FPR+ 1) / 220
LCDC_FPR = 55574
WRITE COMMAND “0xE6”
WRITE DATA “0x00” (LCDC_FPR = 55574)
WRITE DATA “0xD9”
WRITE DATA “0x16”
For serial LCD interface:
Configure the pixel clock to PLL freq x ((LCDC_FPR + 1) / 220) *4
To obtain PCLK = 5.3MHz with PLL Frequency = 100MHz,
5.3MHz = 100MHz * ( ( LCDC_FPR+ 1) / 220 )*4
LCDC_FPR = 13892
WRITE COMMAND “0xE6”
WRITE DATA “0x00” (LCDC_FPR = 13892)
WRITE DATA “0x36”
WRITE DATA “0x44”
9.73 get_lshift_freq
Command
Parameters
Command
Parameter 1
Parameter 2
Parameter 3
0xE7
3
D/C
D7
D6
D5
D4
D3
D2
D1
D0
Hex
0
1
1
1
0
0
1
1
1
E7
0
0
0
0
1
LCDC_FPR19 LCDC_FPR18 LCDC_FPR17 LCDC_FPR16
xx
1
LCDC_FPR15 LCDC_FPR14 LCDC_FPR13 LCDC_FPR12 LCDC_FPR11 LCDC_FPR10 LCDC_FPR9 LCDC_FPR8
xx
1
LCDC_FPR7 LCDC_FPR6 LCDC_FPR 5 LCDC_FPR4 LCDC_FPR 3 LCDC_FPR2 LCDC_FPR1 LCDC_FPR0
xx
Description
Get the current LSHIFT (pixel clock) frequency setting
Solomon Systech
Jan 2010
P 76/93
Rev 1.1
SSD1963
LCDC_FPR[19:16] : The highest 4 bits for the pixel clock frequency settings. (POR = 0111)
LCDC_FPR[15:8] : The higher byte for the pixel clock frequency settings. (POR = 11111111)
LCDC_FPR[7:0] : The low byte for the pixel clock frequency settings. (POR = 11111111)
SSD1963
Rev 1.1
P 77/93
Jan 2010
Solomon Systech
9.74 set_pixel_data_interface
Command
Parameters
Command
Parameter 1
0xF0
1
D/C
0
1
D7
1
0
D6
1
0
D5
1
0
D4
1
0
D3
0
0
D2
0
A2
D1
0
A1
D0
0
A0
Hex
F0
xx
Description
Set the pixel data format to 8-bit / 9-bit / 12-bit / 16-bit / 16-bit(565) / 18-bit / 24-bit in the parallel host processor
interface. This command is used for display data only, the command format is always 8 bit.
A[2:0] : Pixel Data Interface Format (POR = 101)
000
8-bit
001
12-bit
010
16-bit packed
011
16-bit (565 format)
100
18-bit
101
24-bit
110
9-bit
Others Reserved
* Note : The un-used data bus will be driven to ground by SSD1963, so don’t connect the un-used data bus to
MCU.
9.75 get_pixel_data_interface
Command
Parameters
Command
Parameter 1
0xF1
1
D/C
0
1
D7
1
0
D6
1
0
D5
1
0
D4
1
0
D3
0
0
D2
0
A2
D1
0
A1
D0
1
A0
Hex
F1
xx
Description
Get the current pixel data format settings in the parallel host processor interface.
A[2:0] : Pixel Data Interface Format (POR = 101)
000
8-bit
001
12-bit
010
16-bit packed
011
16-bit (565 format)
100
18-bit
101
24-bit
110
9-bit
Others Reserved
Solomon Systech
Jan 2010
P 78/93
Rev 1.1
SSD1963
10 MAXIMUM RATINGS
Table 10-1: Maximum Ratings (Voltage Referenced to VSS)
Symbol
VDDD
VDDPLL
VDDLCD
VDDIO
VIN
VOUT
TSOL
TSTG
TA
Parameter
Digital Core power supply
PLL power supply
LCD Interface power supply
I/O power supply
Input Voltage
Output Voltage
Solder Temperature / Time
Storage temperature
Operating temperature
Value
-0.5 to 1.8
-0.5 to 1.8
-0.5 to 4.6
-0.5 to 4.6
-0.5 to 4.6
-0.5 to 4.6
225 for 40 sec max at solder ball
-45 to 125
-30 to 85
Unit
V
V
V
V
V
V
o
C
o
C
o
C
Maximum ratings are those values beyond which damages to the device may occur. Functional operation should be restricted to the
limits in the Electrical Characteristics tables or Pin Description section
This device contains circuitry to protect the inputs against damage due to high static voltages or electric fields; however, it is advised
that normal precautions be taken to avoid application of any voltage higher than maximum rated voltages to this high impedance
circuit. For proper operation it is recommended that VIN and VOUT be constrained to the range VSS < (VIN or VOUT) < VDDIO. Reliability
of operation is enhanced if unused input is connected to an appropriate logic voltage level (e.g., either VSS or VDDIO). Unused outputs
must be left open. This device may be light sensitive. Caution should be taken to avoid exposure of this device to any light source
during normal operation. This device is not radiation protected.
11 RECOMMENDED OPERATING CONDITIONS
Table 11-1: Recommended Operating Condition
Symbol
VDDD
VDDPLL
VDDLCD
VDDIO
Parameter
Digital Core power supply
PLL power supply
LCD Interface power supply
I/O power supply
Min
1.10
1.10
1.65
1.65
Typ
1.2
1.2
3.3
3.3
Max
1.30
1.30
3.6
3.6
Unit
V
V
V
V
11.1 Power-up sequence
Figure 11-1: Power-up Sequence
Note
Clock reference is only applicable when CLK is used.
SSD1963
Rev 1.1
P 79/93
Jan 2010
Solomon Systech
12 DC CHARACTERISTICS
Conditions:
Voltage referenced to VSS
VDDD, VDDPLL = 1.2V
VDDIO, VDDLCD = 3.3V
TA = 25°C
Table 12-1 : DC Characteristics
Symbol
PSTY
IIZ
IOZ
VOH
VOL
VIH
VIL
Parameter
Quiescent Power
Input leakage current
Output leakage current
Output high voltage
Output low voltage
Input high voltage
Input low voltage
Test Condition
Min
Typ
300
Max
500
1
1
Unit
uW
uA
uA
V
0.2VDDIO
V
VDDIO + 0.5
V
0.2VDDIO
V
-1
-1
0.8VDDIO
0.8VDDIO
13 AC CHARACTERISTICS
Conditions:
Voltage referenced to VSS
VDDD, VDDPLL = 1.2V
VDDIO, VDDLCD = 3.3V
TA = 25°C
CL = 50pF (Bus/CPU Interface)
CL = 0pF (LCD Panel Interface)
13.1 Clock Timing
Table 13-1: Clock Input Requirements for CLK (PLL-bypass)
Symbol
FCLK
TCLK
Parameter
Input Clock Frequency (CLK)
Input Clock period (CLK)
Min
Max
110
Units
MHz
ns
1/fCLK
Table 13-2 : Clock Input Requirements for CLK
Symbol
FCLK
TCLK
Parameter
Input Clock Frequency (CLK)
Input Clock period (CLK)
Min
2.5
1/fCLK
Max
50
Units
MHz
ns
Table 13-3 : Clock Input Requirements for crystal oscillator XTAL
Symbol
FXTAL
TXTAL
Solomon Systech
Parameter
Input Clock Frequency
Input Clock period
Min
2.5
1/fXTAL
Jan 2010
Max
10
P 80/93
Units
MHz
ns
Rev 1.1
SSD1963
13.2 MCU Interface Timing
13.2.1 Parallel 6800-series Interface Timing
Table 13-4: Parallel 6800-series Interface Timing Characteristics (Use CS# as clock)
Symbol
fMCLK
tMCLK
Parameter
Min
Typ
Max
System Clock Frequency*
1
110
System Clock Period*
1/ fMCLK
Control Pulse High Width Write
13
1.5* tMCLK
tPWCSH
Read
30
3.5* tMCLK
Control Pulse Low Width Write (next write cycle)
13
1.5* tMCLK
tPWCSL
Write (next read cycle)
80
9* tMCLK
Read
80
9* tMCLK
tAS
Address Setup Time
2
tAH
Address Hold Time
2
tDSW
Data Setup Time
4
tDHW
Data Hold Time
1
tPLW
Write Low Time
14
tPHW
Write High Time
14
tPLWR
Read Low Time
38
tACC
Data Access Time
32
tDHR
Output Hold time
1
tR
Rise Time
0.5
tF
Fall Time
0.5
* System Clock denotes external input clock (PLL-bypass) or internal generated clock (PLL-enabled)
Unit
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Figure 13-1: Parallel 6800-series Interface Timing Diagram (Use CS# as Clock)
VIH
D/C
VIL
VIH
R/W
tAS
tAH
VIL
tPLWR / tPLW
CS#
tR
tF
tPWCSL
tPWCSH
VIH
E
VIL
D[17:0]
(WRITE)
Valid Data
VIL
tACC
D[17:0]
(READ)
SSD1963
tDHW
tDSW
VIH
VOL
Rev 1.1
P 81/93
tDHR
VOH
Jan 2010
Valid Data
Solomon Systech
Table 13-5: Parallel 6800-series Interface Timing Characteristics (Use E as clock)
Symbol
fMCLK
tMCLK
Parameter
Min
Typ
Max
System Clock Frequency*
1
110
System Clock Period*
1/ fMCLK
Control Pulse Low Width Write (next write cycle)
13
1.5* tMCLK
tPWCSH
Write (next read cycle)
80
9* tMCLK
Read
80
9* tMCLK
Control Pulse High Width Write
13
1.5* tMCLK
tPWCSL
Read
30
3.5* tMCLK
tAS
Address Setup Time
2
tAH
Address Hold Time
2
tDSW
Data Setup Time
4
tDHW
Data Hold Time
1
tPLW
Write Low Time
14
tPHW
Write High Time
14
tPLWR
Read Low Time
38
tACC
Data Access Time
32
tDHR
Output Hold time
1
tR
Rise Time
0.5
tF
Fall Time
0.5
* System Clock denotes external input clock (PLL-bypass) or internal generated clock (PLL-enabled)
Unit
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Figure 13-2: Parallel 6800-series Interface Timing Diagram (Use E as Clock)
VIH
D/C
VIL
VIH
tAS
tAH
R/W
VIL
tPWCSL
VIH
CS#
tR
VIL
tF
tPWCSH
tPHWR / tPHW
VIH
E
VIH
D[17:0]
(WRITE)
tDHW
tDSW
VIH
Valid Data
VIL
D[17:0]
(READ)
Solomon Systech
tACC
tDHR
VOH
VOL
Valid Data
Jan 2010
P 82/93
Rev 1.1
SSD1963
13.2.2 Parallel 8080-series Interface Timing
Table 13-6: Parallel 8080-series Interface Timing Characteristics
Symbol
fMCLK
tMCLK
Parameter
Min
Typ
Max
System Clock Frequency*
1
110
System Clock Period*
1/ fMCLK
Control Pulse High Width Write
13
1.5* tMCLK
tPWCSL
Read
30
3.5* tMCLK
1.5* tMCLK
13
Control Pulse Low Width Write (next write cycle)
tPWCSH
80
Write (next read cycle)
9* tMCLK
80
Read
9* tMCLK
tAS
Address Setup Time
1
tAH
Address Hold Time
2
tDSW
Write Data Setup Time
4
tDHW
Write Data Hold Time
1
tPWLW
Write Low Time
12
tDHR
Read Data Hold Time
1
tACC
Access Time
32
tPWLR
Read Low Time
36
tR
Rise Time
0.5
tF
Fall Time
0.5
tCS
Chip select setup time
2
tCSH
Chip select hold time to read signal
3
* System Clock denotes external input clock (PLL-bypass) or internal generated clock (PLL-enabled)
Unit
MHz
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
Figure 13-3: Parallel 8080-series Interface Timing Diagram (Write Cycle)
t PWCSL
CS#
PWCSH
VIH
VIL
D/C#
t
t CS
VIH
VIL
t
AH
AS
t
t
F
t
VIH
WR#
R
PWLW
VIL
t
VIH
D[17:0]
SSD1963
VIL
Rev 1.1
P 83/93
DSW
t
DHW
Valid Data
Jan 2010
Solomon Systech
Figure 13-4: Parallel 8080-series Interface Timing Diagram (Read Cycle)
t PWCSL
V
CS#
t PWCSH
IH
V
IL
D/C#
t
CS
VIH
VIL
t
t
AS
AH
t
t
R
F
RD#
t
VIH
PWLR
t
CSH
VIL
t
ACC
t
DHR
VOH
D[17:0]
Valid Data
VOL
Solomon Systech
Jan 2010
P 84/93
Rev 1.1
SSD1963
13.3 Parallel LCD Interface Timing
Figure 13-5: Generic TFT Panel Timing
VT (= 1 Frame)
FPS
VPW
LFRAME
VPS
VDP
LLINE
LDEN
LDATA[17:0]
HT (= 1 Line)
HPW
LPS
LLINE
LSHIFT
LDEN
HDP
HPS
LDATA[17:0]
SSD1963
Rev 1.1
P 85/93
Jan 2010
Solomon Systech
13.4 Serial RGB Interface Timing
Figure 13-6: Serial RGB Interface Timing (without dummy mode)
VT (= 1 Frame)
FPS
VPW
LFRAME
VPS
VDP
LLINE
LDEN
LDATA[17:0]
HT (= 1 Line)
HPW
LPS
LLINE
LSHIFT
LDEN
HDP
HPS
LDATA[7:0]
Solomon Systech
R
G
B
R
G
B
Jan 2010
P 86/93
Rev 1.1
SSD1963
Figure 13-7: Serial RGB Interface Timing (with dummy mode)
VT (= 1 Frame)
FPS
VPW
LFRAME
VPS
VDP
LLINE
LDEN
LDATA[17:0]
HT (= 1 Line)
HPW
LPS
LLINE
LSHIFT
LDEN
HDP
HPS
R
LDATA[7:0]
SSD1963
Rev 1.1
P 87/93
G
Jan 2010
B
R
G
B
Solomon Systech
14 APPLICATION EXAMPLE
Figure 14-1 : Application circuit for SSD1963 (With Direct clock input)
SSD1963
MCU
RESET
CS#
D/C#
E(RD#)
R/W#(WR#)
D[23:0]
Dumb
Display
GPIO1
GPIO2
GPIO3
LFRAME
CONF
LLINE
LDEN
LSHIFT
LDATA[23:16]
CLK
LDATA[15:8]
LDATA[7:0]
GPIO0
XTAL_IN
PWM
TE
2.5-10MHz
SCL
SDA
CS#
VSYNC
HSYNC
DEN
PCLK
R[7:0]
G[7:0]
B[7:0]
SHUT
PWM
1.2V+/-10%
VDDD
Floated
1uF
XTAL_OUT
1.2V+/-10%
VDDPLL
1uF
1.65-3.6V
VDDIO
0.1uF
1.65-3.6V
VDDLCD
Solomon Systech
0.1uF
Jan 2010
P 88/93
Rev 1.1
SSD1963
Figure 14-2 : Application circuit for SSD1963 (With crystal oscillator input)
SSD1963
RESET
CS#
D/C#
E(RD#)
R/W#(WR#)
D[23:0]
MCU
Dumb
Display
GPIO1
GPIO2
GPIO3
LFRAME
CONF
LLINE
LDEN
LSHIFT
LDATA[23:16]
CLK
LDATA[15:8]
LDATA[7:0]
GPIO0
XTAL_OUT
PWM
TE
1.2V+/-10%
120 ohm
2.5-10MHz
XTAL_IN
5pF
SCL
SDA
CS#
VSYNC
HSYNC
DEN
PCLK
R[7:0]
G[7:0]
B[7:0]
SHUT
PWM
VDDD
1uF
5pF
1.2V+/-10%
VDDPLL
1uF
1.65-3.6V
VDDIO
0.1uF
1.65-3.6V
VDDLCD
SSD1963
Rev 1.1
P 89/93
Jan 2010
0.1uF
Solomon Systech
15
PACKAGE INFORMATION
15.1 Package Mechanical Drawing for 80 balls TFBGA
Symbol
A
A1
A2
A3
b
D
E
e
D1
E1
aaa
bbb
ddd
eee
fff
Solomon Systech
Dimension in mm
Min
Typical
---0.16
----0.21
--0.54
0.27
----7.00 BSC
--7.00 BSC
--0.65 BSC
--5.2 BSC
--5.2 BSC
--0.1
--0.2
--0.08
--0.15
--0.08
Jan 2010
Max
1.1
0.26
----0.37
--------------------P 90/93
Rev 1.1
SSD1963
15.2 Package Mechanical Drawing for 128 pins LQFP
Symbol
Min
A
A1
A2
D
D1
E
E1
e
b
SSD1963
Rev 1.1
P 91/93
Dimension in mm
Nom
Max
1.60
0.05
1.40
16.00
14.00
16.00
14.00
0.40 BSC
0.18
Jan 2010
Solomon Systech
15.3 Tape & Reel Drawing for 128 pins LQFP
Solomon Systech
Jan 2010
P 92/93
Rev 1.1
SSD1963
Solomon Systech reserves the right to make changes without notice to any products herein. Solomon Systech makes no warranty,
representation or guarantee regarding the suitability of its products for any particular purpose, nor does Solomon Systech assume any
liability arising out of the application or use of any product or circuit, and specifically disclaims any, and all, liability, including without
limitation consequential or incidental damages. “Typical” parameters can and do vary in different applications. All operating parameters,
including “Typical” must be validated for each customer application by the customer’s technical experts. Solomon Systech does not convey any license under its patent rights nor the rights of others. Solomon Systech products are not designed, intended, or authorized for use
as components in systems intended for surgical implant into the body, or other applications intended to support or sustain life, or for any
other application in which the failure of the Solomon Systech product could create a situation where personal injury or death may occur.
Should Buyer purchase or use Solomon Systech products for any such unintended or unauthorized application, Buyer shall indemnify and
hold Solomon Systech and its offices, employees, subsidiaries, affiliates, and distributors harmless against all claims, costs, damages, and
expenses, and reasonable attorney fees arising out of, directly or indirectly, any claim of personal injury or death associated with such
unintended or unauthorized use, even if such claim alleges that Solomon Systech was negligent regarding the design or manufacture of the
part.
The product(s) listed in this datasheet comply with Directive 2002/95/EC of the European Parliament and of the council of 27
January 2004 on the restriction of the use of certain hazardous substances in electrical and electronic equipment and People’s Republic
of China Electronic Industry Standard SJ/T 11363-2006 “Requirements for concentration limits for certain hazardous substances in
electronic information products (电子信息产品中有毒有害物质的限量要求)”. Hazardous Substances test report is available upon request.
http://www.solomon-systech.com
SSD1963
Rev 1.1
P 93/93
Jan 2010
Solomon Systech