SITRONIX ST2604B

ST2604B
8-bit Integrated Microcontroller
Datasheet
Version 1.1
2009/03/06
Note:
Sitronix Technology Corp.
reserves the right to change the contents
in this document without prior notice.
This is not a final specification. Some
parameters are subject to change.
ST2604B
1
GENERAL DESCRIPTION
The ST2604B is a 8-bit integrated microcontroller designed
with CMOS silicon gate technology. The true static CPU core,
power down modes and dual oscillators design makes the
ST2604B suitable for power saving and long battery life
designs. The ST2604B integrates various logic to support
functions on-chip which are needed by system designers.
small internal display RAM as the buffer of large-sized display.
User may free major internal RAM for computing or temporary
access while keeping the display content. The clock of LCD
(LCDCK) is not only sourced from main-frequency (OSC), it
can also be sourced by OSCX (32KHz crystal) to make current
consumption to be minimum.
The ST2604B features the capacity of memory access of
maximum 44M bytes and DMA function for fast memory
transfer. Six chip-select pins are equipped for direct connection
to external ROM, SRAM, Flash memory or other devices. The
maximum size for a single external memory device can be 16M
bytes.
The ST2604B equips serial communication ports, one UART
and one SPI, to perform different communications, ex.: RS-232
and IrDA, with system components or other products such as
PC, Notebook, and popular PDA. Three clocking outputs can
produce synthesized PWM signals or high frequency carrier for
IR remote control. This helps products become more useful in
our daily life.
The ST2604B has 55 I/Os grouped into 6 ports. They are
Port-A ~ Port-F and Port-L, where the Port-F is 8 open drain
output pins shared with LCD COMs. Each I/O pins can be
programmed to input or output individually. Port-C inputs have
both pull-up and pull-down options. The other input pins have
only pull-up options. In the case of output mode, Port-C outputs
have open-drain type and CMOS type options; while the other
ports are fixed at CMOS type. The Port-A and Port-B are
designed for keyboard scan function. The Port-A inputs are
further equipped with de-bounce and transition triggered
interrupt function. The Port-B/C/D/E/L are shared with other
system functions. All the properties of I/O pins are still
programmable when they are configured to be other special
functional signals. This enlarges the flexibility of the usage of
the functional signals.
The ability of driving large LCD panels, up to 160x160, and
hardware gray-level support rich the display information and
the diversity of contents as well. By the patented sharing
mechanism design of internal memory, the LCD display
function can be done without the need of external display RAM.
The variable LCD buffer design also makes it feasible to use
2/33
The built-in four-channel PSG are designed to generate key
tone, melody, voice, and speech. Two dedicated pins with large
driving capacity can drive a buzzer/speaker directly.
The ST2604B has a Low Voltage Detector (LVD) for power
management usage. The status of internal or external power
can be detected and reported to the management software.
Power bouncing during power-on is a major problem when
designing a reliable system. The ST2604B equips a Low
Voltage Reset function to keep the whole system in reset status
when power is low. After the power returns to normal level, the
system may recover its original states and keeps working
correctly.
With these integrated functions inside, the ST2604B single chip
microcontroller is a right solution for PDA, translator, databank
and other consumer products.
The block diagram of ST2604B is shown in the following figure.
ST2604B
2
BLOCK DIAGRAM
VCC/GND
TEST
VIN
Low Voltage
Detector
Low Voltage
Reset
RESET
Power On
Reset
OSCI
XIO
Clock
Generator
OSC
OSCXO
Clock
Generator
OSCX
A[22:0]
D[7:0]
RD
WR
8-bit
External
Memory
Bus
OSCXI
PVCC/PGND
PSGO/PSGOB
ROM
SRAM
512K bytes 3.5K bytes
DMA
Bank
Control
Logic
Port-D
TCO0/PE0
TCO1/PE1
BCO/PE2
Port-E
PE7~2
Port-E
PF7~0
Port-F
WDT
Transition
Detector
8-bit Static Base Timer
8-bit
CPU
Interrupt
Controller
PSG /
PWM DAC
MMD/CS0
CS5 ~ 1/PD4 ~ 0
CS6/A23/PD5
De-bounce
Logic
SPI
Baud Rate
Generator
Port-A
PA7~0
Port-B
PB6~0
Port-C
INTX/PC0
SCK/PC1
MISO/PC2
MOSI/PC3
SS/PC4
DATA_READY/PC5
Port-C
Port-C
TXD0/PC6
RXD0/PC7
Port-D
TXD1/PD6
RXD1/PD7
Port-L
LD[3:0]/PL3~0
CP/PL4
AC/PL5
LOAD1/PL6
FLM/PL7
UART with
IrDA Mode
Chip Select
Logic
Clocking
Output
Timer
0/1/2/3
- 12 bit
LCD
Controller
LCD
Driver
POFF
BLANK
COM 35~0 LOAD2
SEG 63~0
FIGURE 2-1 ST2604B Block Diagram
3/33
ST2604B
3
n
n
n
n
n
n
n
n
n
n
n
n
n
n
n
n
n
FEATURES
Totally static 8-bit CPU
ROM: 512K x 8-bit
RAM: 3.5K x 8-bit
Stack: Up to 128-level deep
Operation voltage: 2.4V ~ 3.6V
Operation frequency:
– [email protected](Min.)
– [email protected](Min.)
LCD Drives
– COM: 36 outputs. Eight shared with one output port
– SEG: 64 outputs. Shared with 3 I/O ports and memory
bus signals.
One 8x8 Signed Multiplier
Low Voltage Reset (LVR)
– Two levels by code option
Low Voltage Detector (LVD)
– Programmable 4 levels
– System power or external battery level can be detected.
Programmable Watchdog Timer (WDT)
Memory interface to ROM, RAM, Flash
Memory configuration
– Three kinds of banks for program, data and interrupt
– 12-bit bank registers support up to 44M bytes
– Six programmable chip-selects with 4 modes
– Maximum single device of 16M bytes
General-Purpose I/O (GPIO) ports
– Up to 55 bit programmable CMOS I/Os
39 shared with LCD drives
– 8 open drain output pins shared with LCD COMs
– Hardware de-bounce option for Port-A
– Bit programmable pull-up for input pins
– Pull-up/down and open-drain/CMOS control for Port-C
Timer/Counter
– Four 12-bit timers.
– One 8-bit base timer
– Seven fixed base timers
Three clocking outputs
– Clock sources including Timer0/1, baud rate generator
Eleven prioritized interrupts with dedicated exception
vectors
– External interrupt (edge triggered)
– PortA interrupt (transition triggered)
– LCD buffer interrupt
– Base timer interrupt
– Timer0~3 interrupts (x4)
– SPI interrupts (x2)
– UART interrupts (x2)
n
n
n
n
n
n
n
n
n
n
4/33
Dual clock sources with warm-up timer
– Low frequency crystal oscillator (OSCX)
···················································· 32768 Hz
– High frequency resistor or crystal/resonator oscillator
(OSC) selected by pin option .................. 455K~4M Hz
Direct Memory Access (DMA)
– Block-to-Block transfer
– Block to Single port
LCD Power Management
– DC-DC converter with 8-level output control
– LC driving voltage regulator with 16-level control
– 1/4, 1/5, 1/6 bias options with 4 voltage followers
LCD Driver
– 32x28~64x36 resolution, maximum 2304 dots
– Clock source from OSC/OSCX.
– Internal bias resistors(1/4, 1/5, 1/6 bias).
LCD Controller (LCDC)
– Software programmable display size up to 160X160
– B/W, Hardware 4/16 gray levels with 5-bit palette
– Support 1-/4-/8-bit LCD data bus
– Share system memory with display buffer and with no
loss of the CPU time
– LCD buffer extension function to combine both internal
and external RAM for larger display
– Diverse functions including virtual screen, panning,
scrolling, contrast control and alternating signal
generator
Programmable Sound Generator (PSG)
– Four channels with three playing modes:
9-bit ADPCM, 8-bit PCM and 8-bit melody
– One 16-byte buffer and 6-bit volume control per channel
– Wavetable melody support
– Two dedicated PWM outputs for direct driving
– One 12-bit current DAC
Universal Asynchronous Receiver/Transmitter (UART)
– Full-duplex operation
– Baud rate generator with one digital PLL
– Standard baud rates of 600 bps to 115.2 kbps
– Both transmitter and receiver buffers supported
– Direct glueless support of IrDA physical layer protocol
– Two sets of I/Os (TX,RX) for two independent devices
Serial Peripheral Interface (SPI)
– Master and slave modes
– Five serial signals including enable and data-ready
– Both transmitter and receiver buffers supported
– Programmable data length from 7-bit to 16-bit
Three power down modes
– WAI0 mode
– WAI1 mode
– STP mode
Vlcd/LVD trimming fuse function:
–
Vlcd default voltage variation trimming.
–
4-level LVD voltage variation trimming.
ST2604B
4
SIGNAL DESCRIPTIONS
TABLE 4-1 Signal Function Groups
Function Group
Pad No.
Designation
Description
VCC: Power supply for system
Power
VCC , PVCC, AVCC
AVCC: Power supply for LCD function
PVCC: Power supply for PSGO and PSGOB
NOTE: PVCC level must not be higher than VDD level.
GND: System power ground
Ground
GND , PGND, AGND
AGND: Power ground for LCD function
PGND: Power ground for PSGO and PSGOB
RESET : Active low system reset signal input
TEST: Leave this pin open when normal operation
MMD/ CS0 : Memory modes selection pin
RESET ,
System control
Normal mode: Enable internal ROM.
TEST,
MMD/ CS0
MMD/ CS0 is connected to GND.
Emulation mode: Disable internal ROM.
MMD/ CS0 is connected to the chip-select pin of external
ROM. During reset period, the MMD/ CS0 is an internally
pulled-up input pin. After reset cycles, MMD/ CS0 is
changed to be an output pin. It will output signal CS0 .
High frequency oscillator (OSC) mode selected by code-option
Clock
XIO,OSCI
OSCXO,OSCXI, ,
Crystal mode: One crystal or resonator should be connected
between OSCI and XIO
Resistor oscillator mode: One resistor should be connected
between OSCI and VCC
OSCXI, OSCXO: Connect one 32768Hz crystal between these
two pins when using low frequency oscillator
WR / SEG9,
External memory R/W control signals / LCD Segment drivers
External memory
bus signals
RD / SEG8
/ LCD drivers
A[22:0]/SEG32~SEG10
External memory address bus / LCD Segment drivers
D[7:0]/SEG7~SEG0
External memory data bus / LCD Segment drivers
PSG/PWM DAC
PSGO, PSGOB
PSG outputs. Connect to one buzzer or speaker
Keyboard scan
signal (return line)
PA7~0
I/O port A
GPIO / LCD drivers
PB6~0/SEG47~SEG41
I/O port B / LCD Segment drivers
CS5 ~ 1 /PD4~0 /
SEG37~SEG33,
I/O port D and chip-select outputs / LCD Segment drivers
Chip selects / LCD
drivers
UART
SPI
CS6 /A23/PD5 /SEG38
RXD0/PC7,TXD0/PC6,
RXD1/PD7/SEG40,TXD1/
PD6/SEG39
UART signals and I/Os / LCD Segment drivers
DATA_READY /PC5 ,
SS /PC4 , SDO/PC3 ,
SPI signals and I/Os
SDI/PC2 , SCK/PC1
5/33
ST2604B
TABLE 4-2 Signal Function Groups (continued)
Function Group
Pad No.
Designation
Description
External
clock/signal
interrupt
INTX/PC0
Clocking output
BCO/PE2/SEG50 ,
TCO1/PE1/SEG49 ,
TCO0/PE0/SEG48
Clocking outputs / LCD Segment drivers
PE7~3/SEG55~SEG51
I/O port E/ LCD Segment drivers
PL7~0/SEG63~SEG56
I/O port L/ LCD Segment drivers
LCD control signals
LCD control
signals (for
controller mode)
BLANK/COM0,
POFF/COM1,
FLM/COM2,
LOAD1/COM3,
LOAD2/COM4,
AC/COM5,CP/COM6,
EIO/COM7,
LD7~LD0/COM15/COM8
LCD voltage
source
Vout, Vlcd, V1, V2, V3, V4
LCD voltage sources
LCD voltage
booster
C1+, C1-, C2+, C2-
Connect a 0.1 uF between C1+ and C1-, C2+ and C2repectively.
Low Voltage
Detector
VIN
Analog input pin of Low Voltage Dector module
GPIO / LCD drivers
External interrupt inputs
6/33
ST2604B
5
PAD DIAGRAM.
7/33
ST2604B
6
ELECTRICAL CHARACTERISTICS
6.1 Absolute Maximum Rations
*Note: Stresses above those listed under "Absolute Maximum
DC Supply Voltage ---------------------------- -0.3V to +4.5V
Operating Ambient Temperature ---------- -10°C to +60°C
Storage Temperature ------------------------ -10°C to +125°C
Ratings" may cause permanent damage to the device. All the
ranges are stress ratings only. Functional operation of this
device at these or any other conditions above those indicated
in the operational sections of this specification is not implied or
intended. Exposed to the absolute maximum rating conditions
for extended periods may affect device reliability.
6.2 DC Electrical Characteristics
Standard operation conditions: VCC = 3.0V, GND = 0V, TA = 25°C, OSC = 4M Hz, unless otherwise specified
Parameter
Operating Voltage
Symbol
VCC
Min.
Typ.
Max.
Unit
Condition
2.4
3.0
3.6
V
Fosc = 3MHz
2.7
3.0
3.6
V
Fosc = 4MHz
Operating Frequency
F1
-
-
3
MHz
VCC = 2.4V ~ 3.6V
Operating Frequency
F2
-
-
4
MHz
VCC = 2.7 ~ 3.6V
Operating Current
IOP
2.5
3
mA
All I/O port are input and pull-up, execute NOP
instruction, LCDC on
Standby Current
I SB0
450
550
mA
All I/O port are input and pull-up, OSCX on, LCDC off
(WAIT0 mode)
Standby Current
I SB1
3.5
5
mA
All I/O port are input and pull-up, OSCX on, LCDC off
(WAIT1 mode)
Standby Current
I SB2
0.5
1
mA
All I/O port are input and pull-up, OSCX off, LCDC off
(WAIT1 mode)
Standby Current
I SB3
100
130
uA
LCD on, sysck = LCDCK= OSCX, OSC off, Wait0, no
panel (fast B/W mode)
Input High Voltage
V IH
Vcc+0.3
V
Port-C/D/E/L
V
RESET
V
Port-C/D/E/L
0.7Vcc
0.85Vcc
Input Low Voltage
V IL
GND-0.3
Pull-up resistance
Output high voltage
Output low voltage
R IH
VOH1
VOL1
0.7Vcc
Output high voltage
VOH2
0.7Vcc
Output low voltage
VOL2
DAC current
Low Voltage Detector
current
Vlcd variation
0.3Vcc
0.15Vccc
V
0.3Vcc
KW
V
V
150
0.3Vcc
2.4mA
ILVR
3
3.6mA
30
60
-3%
+3%
INT LVD variation
-4%
+4%
EXT LVD variation
-4%
+4%
SPI clock frequency
V
PSG0/PSG0B( in PWM mode), I OH = 35mA.
V
PSG0/PSG0B( in PWM mode), I OL = -65mA.
DAC output current of maximum digital input value
mA
4.0
MHz
8/33
RESET
Port-C/D/E/L (input Voltage=0.7VCC)
Port-C/D/L (IOH =-6mA)
Port-C/D/E/L (IOL =9mA)
Total LVD current consumption
SPI slave mode
ST2604B
6.3 AC Electrical Characteristics
FIGURE 6-1 External Read Timing Diagram
FIGURE 6-2 External Write Timing Diagram
TABLE 6-1 Timing parameters for FIGURE 6-1 and FIGURE 6-2
Standard operation conditions: VCC = 3.0V, GND = 0V, TA = 25°C
Symbol
Characteristic
tSA
tHA
tWLC
tCLWL
tWHCH
tSDW
tHDW
Address setup time
Address hold time
CS “L” pulse width
CS asserted to WR asserted
CS negated after WR is negated
CS asserted to data-out is valid
Data-out hold time after WR is negated
tCLRL
tRHCH
tSDR
tHDR
tR
tF
CS asserted to RD asserted
CS negated after RD is negated
Data-in valid before RD is negated
Data-in hold time after RD is negated
Signal rise time
Signal fall time
9/33
Min.
—
0
166
—
10
—
20
—
10
30
10
—
—
Rating
Typ.
Max.
—
10
—
—
—
—
1/2 tWLC —
—
—
1/2 tWLC —
—
1/2 tWLC
—
—
—
20
10
—
—
—
—
—
—
Unit
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ns
ST2604B
6.4 Characteristic Charts
Frequency of R-OSC as a function of VCC
MHz
Voltage & Frequency
8.00
7.00
6.00
5.00
4.00
3.00
2.00
1.00
0.00
R=31K
R=57k
R=130k
2
2.5
3
3.5
Voltage
FIGURE 6-3 Frequency of R-OSC as a function of VCC
10/33
4
ST2604B
Fosc VS. Rosc
10.00
9.00
3V
8.00
7.00
2.7V
MHz
6.00
2.4V
5.00
4.00
3.3V
3.00
2.00
3.6V
1.00
0.00
1
10
100
1000
Kohm
FIGURE 6-4 Frequency of R-OSC as a function of Resistor
Voltage
Frequency
4MHz
3MHz
2MHz
1MHz
0.5MHz
3V
57K Ohm
80K Ohm
130K Ohm
300K Ohm
600K Ohm
11/33
10000
ST2604B
7
APPLICATION CIRCUITS
ST2604B Application Circuit 1
12/33
ST2604B
ST2604B Application Circuit 2
13/33
ST2604B
ST2604B+ST8008+ST8009 Application Circuit
Note:
LR pin of ST8008 is connected to GND.
L/R bit of ST8009 is configured as low by “interface control selection” instruction
14/33
ST2604B
8
FEATURE COMPARISON OF ST2600 SERIES
Part Number
ROM
RAM
Built-in LCD Driver
Driving LCD with
ext. driver
Dedicated I/O
LCD-Shared I/O
ST2608B
1M Byte
5K Byte
36 COMs X 72
SEGs
~9000 dots (16
gray)
~36000 dots (mono)
24 (PA, PC, PL)
32 (PB, PD, PE,
PF)
LCD gray level
PSG /
volume-control
DAC
Low voltage
detector
Low voltage reset
Watchdog timer
Serieal interface
ST2604B
512K Byte
3.5K Byte
ST2602B
256K Byte
2.5K Byte
ST2601B
128K Byte
1.5K Byte
36 COMs X 64 SEGs
36 COMs X 56 SEGs
36 COMs X 56 SEGs
~6000 dots (16 gray)
~24000 dots (mono)
~4000 dots (16 gray)
~16000 dots (mono)
~2500 dots (16 gray)
~10000 dots (mono)
16 (PA, PC)
8 (PC)
39 (PB[6:0], PD, PE,
31 (PD, PE[6:0], PL,
PL, PF)
PF)
16 gray levels
8 (PC)
31 (PD, PE[6:0], PL, PF)
4-channel wavetable / 64 levels
9-bit PWM, 12-bit current DAC
4 levels
Yes
Yes
UART, SPI, IrDA
Feature Comparison of ST2604 and ST2604B:
Part Number
ROM
RAM
Built-in LCD Driver
Driving LCD with ext. driver
Dedicated I/O
LCD-Shared I/O
Basically functions
LCFG and I/O configure
LCDCK = 32KHz
PSG volume maximum
Vlcd variation(VDD=2.4~3.6)
Vlcd default voltage variation
Current consumption of LVD
DAC
ST2604
512K Byte
3.5K Byte
36 COMs X 64 SEGs
~6000 dots (16 gray)
~24000 dots (mono)
8 (PC) +8 (PA) = 16
39 (PB0~6 PD, PE, PL, PF)
The same
The same
NO
normal
~300mV
-300mV~+300mV
200uA
10-bit
15/33
ST2604B
512K Byte
3.5K Byte
36 COMs X 64 SEGs
~6000 dots (16 gray)
~24000 dots (mono)
8 (PC) +8 (PA) = 16
39 (PB0~6 PD, PE, PL, PF)
The same
The same
YES
2-time larger than ST2604
~50mV
-90mV~+90mV
30uA
12-bit
ST2604B
8.1 LCFG Setting Difference of ST2600 series
ST2608
CFGS[2~0]
00X
010
011
100
101
110
111
SEG0~31
Pad Definition
SEG32 SEG33~38 SEG39 SEG40 SEG41~47 SEG48~55
SEG0~31
No Use
A/D Bus
A/D Bus
SEG0~71
SEG0~63
SEG0~55
SEG0~47
PD0~PD7
PD0~PD6
PD0~PD7
SEG56~63
SEG64~71
PB0~PB7
PB0~PB7
PB0~PB7
PE0~PE7
PE0~PE7
PE0~PE7
PE0~PE7
No Use
No Use
SEG0~31
No Use
PB0~PB7
ST2604B
CFGS[2~0]
Pad Definition
SEG33~39
SEG40 SEG41~47 SEG48~55
SEG0 ~ 63
SEG0 ~ 39
PD7
PB0 ~ 6
PE0 ~ 7
SEG0 ~ 63
SEG0 ~ 55
SEG0 ~ 47
PE0 ~ 7
SEG0 ~ 31
A22
PD0 ~ 7
PB0 ~ 6
PE0 ~ 7
A/D bus
PD0 ~ 7
PB0 ~ 6
PE0 ~ 7
A/D bus
PD0 ~ 7
PB0 ~ 6
PE0 ~ 7
SEG0~31
000
001
010
011
100
101
110
111
SEG32
ST2602
CFGS[2~0]
Pad Definition
SEG33~39
SEG40 SEG41~47 SEG48~55
SEG0 ~ 55
SEG0 ~ 39
PD7
PE0 ~ 6
PL0 ~ 7
SEG0 ~ 55
SEG0 ~ 55
SEG0 ~ 47
PL0 ~ 7
SEG0 ~ 31
A22
PD0 ~ 7
PE0 ~ 6
PL0 ~ 7
A/D bus
PD0 ~ 7
PE0 ~ 6
PL0 ~ 7
A/D bus
PD0 ~ 7
PE0 ~ 6
PL0 ~ 7
SEG0~31
000
001
010
011
100
101
110
111
SEG32
16/33
SEG56~63
PL0 ~ 7
PL0 ~ 7
PL0 ~ 7
PL0 ~ 7
PL0 ~ 7
PL0 ~ 7
PE0~PE7
ST2604B
9
CHECKLIST OF ST2604B
CHEKLIST of ST2604B-□ □ □ □
8-Bit Microcontroller With 512K Bytes ROM
CODE OPTION
LOW VOLTAGE RESET
OSCILLATOR
OPERATING VOLTAGE
□ 1.4 Volt
□ 2.1 Volt
□ 32768 Hz Crystal
□ R-OSC
MHz (Resistor =
□ Resonator □ Crystal
MHz
□ 2.4V ~ 3.6V
□ Regulator
□ 2.7V ~ 3.6V
V
KΩ )
□ Other Range
~
V
Note: Maximum operating frequency = 4.0 [email protected]~3.6V, 3.0 [email protected]~3.6V
BATTERY
POWER DOWN MODES
LOW VOLTAGE DETECTOR
□ CR20
x
□ AAx
□ WAI-0
□ WAI-1
Disabled
□ Internal-LVD level1(2.4V)
□ Internal-LVD level3(2.8V)
□ External-LVD level1(1.2V)
□ External-LVD level3(1.4V)
□ AAAx
□
□
□
□
□
Internal-LVD
Internal-LVD
External-LVD
External-LVD
level2(2.6V)
level4(3.0V)
level2(1.3V)
level4(1.5V)
UART
SPI
□ Enabled, Baud Rate:
□ Enabled, Bit Rate:
ST2600B EV
mode Selection
Please check ST2600B
DVB (PCB-300A)
□ST2602B EV mode: JP58 2à3
JP59 1à2
□ST2604B EV mode: JP58 1à2
JP59 2à3
□ST2608B EV mode: JP58 2à3 JP59 2à3
LCD SPECIFICATIONS
Resolution:
Frame Rate:
x
Hz
bps
bps
□ Disabled
□ Disabled
Duty: 1/
Bias: 1/
VLCD:
V
Alternation: Every □ Frame □
Lines
Driver: □ ST8012x
□ ST8008x
LCD Gray-level
□ Black and White
□ 4 Gray-level
PSG mode
Current-type DAC
□
PWM-single pin □
Register Value
When playing sound: the PSGC =
,
When LCD is on: LCKR=
, LCTR=
, LFRA =
LYMAX=
, LPOW =
LREG =
, LCFG =
When LVD is on: LVCTR =
(WAIT0 or WAIT1)
When power down: SYS =
Data sheet
ST2604B user’s manual Ver
CODE FILE:
□ ST8009x
□ ST8011x
□ 16 Gray-level
PWM-two pin push pull □ PWM-two pin two end
.BIN
DATE(Y/M/D):
17/33
20
/
,LXMAX=
/
,
ST2604B
CHECK SUM:
Note:
□ □ □ □
H (Byte Mode)
a. File format must be binary and the extension should be “.BIN”.
b. File should be wrapped in ZIP format for transferring or e-mailing.
c. Only single file is allowed.
d. File length is 512K bytes.
e. Functions should be checked on the emulation board or by real chip.
f. Electric characteristics of the emulation board are not identical with those of the real chip.
CUSTOMER
COMPANY
SIGNATURE
SITRONIX
FAE/SA
SALSE
18/33
ST2604B
Project Name
DATE:
ITEM
CHECK
1.
2.
3.
4.
Make sure the resistor of R-OSC matches the desired frequency and VCC
Make sure the referenced data sheet is the most updated version
After power on, enter wait-0 mode for0.5 second before normal operation
Initialize user RAM and every related control register
Confirm Vlcd level, duty, bias, frame rate, alternating rate and the display quality of
5. LCD
6. Make sure to set LCKR=00h before turning off LCD function
Make sure to implement a mechanism to fine-tune LCD contrast level. The
7. mechanism could be pin-option or keying-adjustment.
8. Confirm PSG output mode: Current DAC or one of three PWM modes
Before entering power down mode, turn off unused peripheral such as LCD
9. controller, PSG, Current DAC and LVD
Confirm I/O direction, default state and function-enable bits. Enable pull-up for
10. unused input pins
Read from an input port after the signals are stable. Ex. when doing key scan,
11. delay 12 us from a new scan value then read the return lines.
If an input connects to VCC or GND directly, make sure to remove any DC current
12.
from internal pull-up/down resistor after the status is read.
Do not use “read-modify-write” instructions, e.g. ROR and SMB0, to the registers
that are read-only, write-only or have different functions for read and write. The
registers at least include PA ~ PF, PL, PCL, PSGxA, PSGxB, TxCH, TxCL, PRS,
13. BTSR, BTC, MULL, MULH, MISC, SYS, IREQL, IREQH, LSSAL, LSSAH, LVPW,
LCKR, LFRA, LPAL, SDATAH, SDATAL, SSR, DMSL, DMSH, DMDL, DMDH,
DCNTL, DCNTH, LVCTR, UDATA and USR.
14. Disable unused functions and reserve “RTI” instruction for unused interrupt vectors
Always disable interrupt function (by an ‘SEI’instruction) when modifying the
15. IENAL, IENAH, IREQL and IREQH registers.
16. Check stack memory is limited within 256 bytes.
17. Design a test mode to check every possible function
18. Follow the standard operation flow of using LCDCK=32KHz.
19 Use ST2600B (enable ST2604B EV mode), to develop the whole system., and
verify every functions, especially sound quality and LCD performance.
20 RC-type OSC has inter-sample variation.
For frequency-sensitive application (for example:IR communication and speech
sampling rate) , please use 32KHz_OSC to calibrate RC-type OSC by firmware
21 Fill up ROM until there has no empty place. (total 512K bytes)
22 Make sure LCKR[5]=0
Engineer
Manager
19/33
NOTE
ST2604B
ST26xxB application note:
Content:
1.
2.
3.
4.
5.
6.
7.
8.
9.
10.
11.
12.
13.
14.
15.
16.
17.
18.
19.
20.
PSG: Current-DAC and PWM application circuit
Methods to make up LCD voltage deviation
Vertical Cross talk on LCD display
How to use IrDA mode to generate 38kHz carrier with data?
LCDCK=32k clock source on ST2602B/ST2608B display
System clock switching from OSC to OSCX
Measure RC-OSC system clock
IrDA mode application note
ST26xx UART details
IrDA BGRCK generation source
OC-OSC / X’tal application circuit
LCD blink cause by PSG
How to measure the internal current of ST2600B?
Ways to save power consumption
32KHz (OSCX) application circuit
ST26XX+ST8008 CASCADE MODE CONNECTION
Standard flow for switching I/O and segment
LCDCK=32K with cascade mode
User Manual for ST2600B external bus usage
Pull-up resistance of D0~D7 for current issue when using ST75xx
Version 1.09
20/33
ST2604B
<PSG: Current-DAC and PWM application circuit>
Description:
(These AP circuits are suitable for ST26xx series IC)
Figure 1 PWM mode application circuit
Figure 2 Current-DAC mode application circuit
21/33
ST2604B
<Methods to make up LCD voltage deviation >
Notice1: In order to cover the variation of VLCD of LCD panel, be sure to reserve pin-option by GPIO to
change the status of VLCD( bit0:3 of register LREG). Here we suggest that there are at least
5-level of voltage pin-option for VLCD. If the GPIO is not enough to make pin-option,
programmer can use key-return-line method for power on pin-option.
For example: make pin-option for change VLCD at… /5.6/5.8/6.0V/6.2V/6.4/…
Notice2: Programmer should add a contrast controller function to adjust VLCD for the convenience of
end-user to change the contrast as they like.
For example: VLCD is pre-set at 6.2 by pin-option, end-users can also adjust the
contrast… /5.8/5.9V/6.0V/6.2V/6.2V/6.3/6.4/… by using contrast controller function.
Notice3: Verifying the performance of voice on ST2602/2604/2608 DEMO boards.
Because ST2600B DVB
can not provide the totally voice efficacy, such like the volume and the quality of voice. So we strongly
suggest to verify voice playing on ST2602B/ST2608B DEMO boards before MASK.
(Ps… Because LCD SEG pins are shared with external EPROM, so the picture can not be verified on
DEMO boards.)
<Vertical Cross talk on LCD display>
Description: Vertical Cross talk on LCD display
Solution: Vertical cross talk usually happens when the differential voltage of V0~V4 are not closely. In this case,
increase C0~C4 (recommend > 1uF) will eliminate this problem. Fine tuning the value of capacitance
to get the best LCD quality.
22/33
ST2604B
<How to use IrDA mode to generate 38kHz carrier with data?>
Port-E-2 (PE2) is shared with clock signal output function, and the frequency of this pin is programmable.
Programmer can define which signal pattern is "0", and which signal is "1"
For example, using Timer_interrupt to enable/disable PE2 function, and programmers can produce the signal
pattern which means "0" or "1"
The same way, receive side can decode the signal by encode information.
23/33
ST2604B
<LCDCK=32k clock source on ST2602B/ST2608B display>
(1) Control register
Address Name R/W
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
$047 LCTR
LPWR
BLNK
REV
CAS
GL[3]
R/W
Bit 3~2: GL[3:2] : LCD gray-level selection bit
00 = B/W.
01 = 4 gray
10 = 16gray
11 = fast B/W mode
(2)
Address Name
R/W
Bit 7
Bit 6
Bit 5
Bit 4
Bit 3
$048 LCKR
W
LMOD[1] LMOD[0] LCK[3]
Bit [5:4]:
Bit 2
GL[2]
Bit 2
LCK[2]
Bit 1
GL[1]
Bit 1
LCK[1]
Bit 0
GL[0]
Bit 0
LCK[0]
Default
1000 0000
Default
- - 00 0000
LMOD : LCD data bus mode selection
00 = 1-bit mode
01 = 4-bit mode
1X = 8-bit mode
Bit 3~0: LCKR[3:0] : LCD clock selection (when SYSCK=OSCK)
LCKR[3:0]
0000
0001
0010
0011
0100
0101
0110
0111
1000
1001
1010
1011
1100
1101
1110
1111
LCDCK (B/W, 4G, 16G mode)
LCDCK (fast B/W mode)
1-bit mode
4-bit mode
8-bit mode
1-bit mode
4-bit mode
8-bit mode
(LMOD=00) (LMOD=01) (LMOD=1X) (LMOD=00) (LMOD=01) (LMOD=1X)
SYSCK
SYSCK/8
SYSCK/2
SYSCK/16
SYSCK /4
SYSCK /32
SYSCK /6
SYSCK /48
SYSCK /8
SYSCK /64
SYSCK /10
SYSCK /80
SYSCK /12
SYSCK /96
SYSCK /14
SYSCK /112
SYSCK /16
SYSCK /128
SYSCK /18
SYSCK /144
SYSCK /20
SYSCK /160
SYSCK /22
SYSCK /176
SYSCK /24
SYSCK /192
SYSCK /26
SYSCK /208
SYSCK /28
SYSCK /224
SYSCK /30
SYSCK /240
(3) Sysclk is RC:
1. Lcd clock source is Sysclk. If Sysclk is RC, LCD clock source will be RC.
2. In ST2602B, if LCD clock source is RC, B/W, 4G, 16G mode are the same as ST2602.
3. The fast B/W mode is added. In fast B/W mode, the LCDCK will be divided by 8.
4. IF Sysclk is RC and in fast B/W mode, the frame rate is determined as below.
Frame Rate =
LCDCK
( LXMAX + LFRA + 1) × ( LYMAX * 2)
(4) Sysclk is 32K:
1. If Sysclk is 32k, LCD clock source will be 32k.
2. If Sysclk is 32k, LCD can only display B/W.
3. If LCD clock source is 32k, please set GL[3:2]=11(fash B/W mode) . In this condition, LCKR and LPAN control registers
will avoid. LCDCK is always 32k hz and the frame rate is only controlled by LFRA control register.
4. If LCD clock source is 32k, DC-DC converter clock (LPCK) will also become 32k. So, user must to change LPCK register
to get higher pump frequency(We will provide a macro to take care this part).
5. IF Sysclk is 32K and in fast B/W mode, the frame rate is determined by below equation.
Frame Rate =
LCDCK
, where LCDCK is 32K hz.
( LXMAX + LFRA + 1) × ( LYMAX * 2)
(5) change Sysclk from RC to 32K
Step1: let LCD in fast B/W mode
Step2: use the macro “SWITCH_SYSCLK_RC_TO_32K” to change Sysclk to 32K
(6) change Sysclk from 32K to RC
24/33
ST2604B
Step1: use the macro “SWITCH_SYSCLK_32K_TO_RC ” to change Sysclk to RC
(7) sample code
1. When B/W, 4G, 16G mode change to fast B/W mode or fast B/W mode change to B/W, 4G, 16G mode, must turn off LCD.
for example: B/W, 4G, 16G mode change to fast B/W mode.
;====Step1 LCD OFF ===
LDA LCTR
ORA #10000000B
STA
LCTR
;====Step2 set GL[3:2]=11, fast B/W mode ===
LDA LCTR
ORA #00001100B
STA
LCTR
;=== Step3 set Frame rate about 65 Hz ===
LDA #6
;when Sysclk is changed to 32k, LFRA can’t be modified. Thus LFRA
STA
LFRA
;is determined by equation2. Let the frame rate in sysclk=32k mode is
;about 65hz
LDA #00001000B
;since LFRA has been determined, LCKR is determined by frame rate equation.
STA
LCKR
;Let the frame rate in Sysclk=RC mode is about 65hz
;===Step4 LCD ON ===
LDA LCTR
AND #~10000000B
STA
LCTR
[After setting up fast B/W mode, then switch SYSCK from RC to 32k]
2. Sysck from RC change to 32k…
Please use the macro “SWITCH_SYSCLK_RC_TO_32K”.
This macro will use 4 bytes RAM. They are show below.
;===== used ram ====
LCD_FLAG
DS 1
IENAL_BAK
DS 1
IENAH_BAK
DS 1
LPCK_BAK
DS 1
And this macro will also use LCD interrupt. Please copy below program in LCD interrupt service routine.
;==== LCD interrupt service routine ===
LCDFR_ISR:
PHA
LDA #FFH
STA
LCD_FLAG
RMB7
IENAL
;DISABPLE LCD INTERRUPT
PLA
RTI
The declaration of this macro is show below (please don’t modify this macro)
SWITCH_SYSCLK_RC_TO_32K
.MACRO
;=== backup LPCK ===
LDA LPCK
STA
LPCK_BAK
LDA #2
STA
LPCK
;=== BACKUP IENAL/H AND ONLY ENABLE LCD INT ===
SEI
LDA IENAL
STA
IENAL_BAK
LDA IENAH
STA
IENAH_BAK
LDA #10000000B
;ONLY ENABLE LCD INT
STA
IENAL
STZ
IENAH
LDA #01111111B
25/33
ST2604B
STA
IREQL
STZ
LCD_FLAG
CLI
?WAIT_LCD_INT_RC232K:
LDA LCD_FLAG
BEQ ?WAIT_LCD_INT_RC232K
;CLEAR LCD INT REQUEST
;=== change SYSCLK = 32K ===
LDA SYS
ORA #10000000B
STA
SYS
NOP
NOP
NOP
BBR7 SYS,$
;=== RECOVERY IENAL/H ===
SEI
LDA IENAL_BAK
STA
IENAL
LDA IENAH_BAK
STA
IENAH
CLI
.ENDM
3. Sysck from 32K change to RC. (After changing to RC, LCD must be in fast B/W mode.)
Please use the macro “SWITCH_SYSCLK_32K_TO_RC”.
SWITCH_SYSCLK_32K_TO_RC
.MACRO
;=== BACKUP IENAL/H AND ONLY ENABLE LCD INT ===
SEI
LDA IENAL
STA
IENAL_BAK
LDA IENAH
STA
IENAH_BAK
LDA #10000000B
;ONLY ENABLE LCD INT
STA
IENAL
STZ
IENAH
LDA #01111111B
STA
IREQL
;CLEAR LCD INT REQUEST
STZ
LCD_FLAG
CLI
?WAIT_LCD_INT_32K2RC:
LDA LCD_FLAG
BEQ ?WAIT_LCD_INT_32K2RC
;=== change SYSCLK = RC ===
LDA SYS
AND #~10000000B
STA
SYS
NOP
NOP
NOP
BBS7 SYS,$
;=== RECOVERY IENAL/H ===
SEI
LDA IENAL_BAK
STA
IENAL
LDA IENAH_BAK
STA
IENAH
CLI
LDA LPCK_BAK
STA
LPCK
.ENDM
26/33
ST2604B
<System clock switching from OSC to OSCX>
Cause warm-up time is different when OSC is RC-OSC or X’tal.
To make sure the system clock has switched to OSCX, or error will happen.
Sample code, please follow up…
LDA
SYS
ORA
#80H
STA
SYS
;switch OSC to OSCX
NOP
NOP
NOP
BBR7 SYS,$ ; branch self until OSC is changed to OSCX
<Measure RC-OSC system clock>
Since programmer wants to measure the system clock when using RC-OSC, please follow up.
Please connect a 3K-Ohm resistor between Vdd and XIO. You can get a periodic signal output from the XIO
pin. It's RC osc signal.
<IrDA mode application note>
Since IrDA has strictly protocol when transmit/receive data.
We suggest programmers use X’tal to be system clock instead of RC-OSC if IrDA signals are needed.
Programmer can use ceramic-OSC to gain some profit since it’s cheaper than X’tal.
27/33
ST2604B
<ST26xx UART details>
BGRCK: BGRCK is used to produce UART baud rate,
and BGRCK comes from OSC(main frequency)
and fine tuning by 32768Hz crystal(REF) to make output baud rate is a stable frequency signal and will
not effected by VDD variation.( RC-OSC frequency will change when VDD changes.)
Baud rate: Baud rate comes from BGRCK, and is determined by BDIV and BRS registers. The “Error rate”
of baud rate is the maximum positive/negative inaccuracy of output baud rate.
For example: If baud rate = 9600bps and OSC is in the rage of 3.72~4.28MHz, programmer should set BRS=61, BDIV=13
to get the best output baud rate which has error of 0.1%.So the real output baud rate will be in the range of
[9600x0.999:9600x1.001].
28/33
ST2604B
< IrDA BGRCK generation source >
BGRCK can be generated by two ways.
1. When bit7 of BCTR is 0,Haredware PLL which is used to stable BGRCK output will be operated. Cause
BGRCK comes from OSC, since RC-OSC can’t produce stable frequency, ST26xx hardware will fine tune
BGRCK output frequency referenced from 32768Hz crystal to make BGRCK is in the range no matter VDD
variation.
2. When bit7 of BCTR is 1:
It’s used when OSC is X’tal. Since X’tal can produce stable frequency, and BGRCK comes from OSC, so
BGRCK will also be stable if OSC is X’tal. Programmer can get better BGRCK output to make UART signal
much more accurate by this way.
When bit7 of BCTR is 1, UART baud rate will be get in the following formula:
baud rate = Sysclk/(BDIV*16) (no need to set “BRS”)
< How to avoid LCD blink caused by PSG >
Description:
LCD display may blink when LCD function and PSG function are playing in the same time. LCD blink caused by CPU can ’t
stand the load of calculation. So the LCD display my lag. And We can find there has blink problem.
Solution:
By using internal DMA function to move LCD data instead of programming method can solve part of this kind of problem. If
there still has the same problem, we can separate LCD data into 16 parts and use DMA method to move into LCD RAM. The
LCD blink problem can be totally solved.
Example program can be found by SA engineer. !!Please email us!!!
< How to measure the internal current of ST2600B?>
When finish developing program by ST2600B, programmer should measure the current consumption of totally possible
situations. In that time programmer can use ST2600B stand alone mode with running external ROM. In order to only measure
the current from IC, the power for External ROM should be independent. And then we can measure the current from IC only!!
< Ways to save power consumption >
There are some factors which can effect current consumption…
(1) Main-frequency : Higher frequency needs more current
(2) DAC mode cost much current than PWM mode
(3) Vlcd voltage level : Higher Vlcd pays higher current.
(4) Using EPROM will cost more current than no use.
(5) Input without any connection will randomly cost power
(6) WAIT mode with considerable program can save lots of power
(7) Larger panel will pay more current.
(8) Un-ideal hardware connection will cause unknown current waste.
29/33
ST2604B
<32KHz (OSCX) application circuit >
Below shows the application circuit of 32KHz X’tal connection. Please follow it.
The original application circuit as below:
The modified circuit as follow:
<ST26XX+ST8008 CASCADE MODE CONNECTION>
This interface is suitable for ST26xx series IC.
Notice: ST26xxB can only output common signal when cascade mode.
User can not mix the segment from ST26xxB and the segment from other LCD drivers. It’s because the LCD
driving ability of ST26xxB and other LCD drivers are not the same. If user mix them, the performance of LCD display
may be bad. (Color block or cross-talk)
30/33
ST2604B
< Standard flow for switching I/O and segment >
We know that there are many I/O which are shared with LCD segment.
And the configure is determined by LCFG register.
Here is the standard flow of configure I/O or segment, please follow up. Or programmer will not configure I/O possibly.
(1) Please configure LCFG first!!
(2) And then configure PCA/PCB/PCC/PCD/PCE/PCL
(3) Finally configure PA/PB/PC/PD/PE/PL
Sample code:
LDA
#FFH
STA
LCFG
STA
PCL
STA
PL
; enable all I/O
; configure PL as output
; PL0~PL7 high status
< LCDCK=32K with cascade mode >
There has some limit when programmer use LCDCK=32K and cascade.
Programmer can use ST26 with LCD cascade mode, it's no doubt. Also, programmer can use cascade mode
combine with LCDCK from 32KHz(OSCX).
But user should take care one thing as following:
We know ST26 can support Cascade 1/2/4-bit data bus mode, however, LCDCK=32K function can only support
8-bit mode!!
So, when programmer use these two functions in the same time, MCU will push 8-bit data per clock cause
LCDCK=32K function, but cascade mode maximum push 4-bit data out to LCD driver per clock, so you will lose
4-bit data(bit4~bit7) and make display data wrong.
The solution is to modify the picture, let MCU push 8-bit every clock, and we separate it every 4-bit data into 8 bit
data as picture 2. and we can solve it. Mention that because LCDCK=32K can maximum load 36 x 80 dots picture, by
above condition, we finally can push 36x40 dots picture to show on LCD since we only use half of data (first 4-bit).
ßThe original picture information
bit0~bit7
bit8~bit15
bit16~bit23
ßpicture 2 : modified picture
Notice: ST26xxB can only output common signal when cascade mode.
User can not mix the segment from ST26xxB and the segment from other LCD drivers. It’s because the LCD
driving ability of ST26xxB and other LCD drivers are not the same. If user mix them, the performance of LCD display
may be bad. (Color block or cross-talk)
< User Manual for ST2600B external bus usage >
[Description]
Since users may use external memory bus to access external ROM, FLASH, or LCD driver, we draw this manual to tell the
31/33
ST2604B
details and notice when using external bus by ST2600B in two mode: (1)Stand alone mode (2) ICE-mode
(1) When using ST2600B Stand alone mode:
External memory bus can be output directly by ST2600B DVB (PCB-300) J22 pin-1 to pin-32
(2) When using ST2600B ICE mode:
Because external data can be controlled by PC through ST-ICE, so the external bus will be shared with ICE connector
pins (PCB-300 - J15)
(a) Please first amount 74hc32 on U11 and U12.
(b) PCB-300 J15 pins allocation as following:
(c) ST2600B DVB should be connected to ST-ICE by J15, and also be connected to external bus by above
table
< Pull-up resistance of D0~D7 for current issue when using ST75xx >
Description: When entering sleep mode, D0~D7 of ST75xx will be floating, and make current consumption (about 120uA). It
can be solved by adding 8 1M-ohm resistance on D0~D7.
32/33
ST2604B
10
REVISIONS
REVISION
DESCRIPTION
PAGE
DATE
V1.0
V1.1
Add ST26xx application note
2009/3/9
The above information is the exclusive intellectual property of Sitronix Technology Corp. and shall not be disclosed, distributed or reproduced
without permission from Sitronix. Sitronix Technology Corp. reserves the right to change this document without prior notice and makes no
warranty for any errors which may appear in this document. Sitronix products are not intended for use in life support, critical care, medical,
safety equipment, or similar applications where products failure could result in injury, or loss of life, or personal or physical harm, or any
military or defense application, or any governmental procurement to which special terms or provisions may apply.
33/33