ETC W78E365P-40

Preliminary W78E365
8-BIT MICROCONTROLLER
GENERAL DESCRIPTION
The W78E365 is an 8-bit microcontroller which has an in-system programmable FLASH EPROM for
firmware updating. The instruction set of the W78E365 is fully compatible with the standard 8052. The
W78E365 contains a 64K bytes of main FLASH EPROM and a 4K bytes of auxiliary FLASH EPROM
which allows the contents of the 64KB main FLASH EPROM to be updated by the loader program
located at the 4KB auxiliary FLASH EPROM; 1K bytes of on-chip AUX RAM; four 8-bit bi-directional
and bit-addressable I/O ports; an additional 4-bit port P4; three 16-bit timer/counters; a serial port.
These peripherals are supported by a eight sources two-level interrupt capability. To facilitate
programming and verification, the FLASH EPROM inside the W78E365 allows the program memory to
be programmed and read electronically. Once the code is confirmed, the user can protect the code for
security.
The W78E365 microcontroller has two power reduction modes, idle mode and power-down mode, both
of which are software selectable. The idle mode turns off the processor clock but allows for continued
peripheral operation. The power-down mode stops the crystal oscillator for minimum power
consumption. The external clock can be stopped at any time and in any state without affecting the
processor.
FEATURES
•
Fully static design 8-bit CMOS microcontroller up to 40 MHz.
•12
clocks per machine instrument cycle
•
64K bytes of in-system programmable FLASH EPROM for Application Program (APROM).
•
4K bytes of auxiliary FLASH EPROM for Loader Program (LDROM).
•
1K +256 bytes of on-chip RAM. (including 1K bytes of AUX-RAM, software selectable)
•
64K bytes program memory address space and 64K bytes data memory address space.
•
5 channels PWM (P1.3~P1.7 software controlable)
•
Four 8-bit bi-directional ports.
•
Additional direct LED drive outputs through P4.4 ~ P4.7 ( only for 48-pin LQFP package)
•
Three 16-bit timer/counters
•
One full duplex serial port
•
Eight-sources, two-level interrupt capability
• Watchdog timer
•
Built-in power management
•
Code protection
•
PACKAGE
− PDIP 40: W78E365-24/40
−PLCC 44: W78E365P-24/40
− PQFP 44: W78E365F-24/40
−LQFP 48: W78E365D-24/40
-1-
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
PIN CONFIGURATIONS
40-pin DIP (W78E365)
T2, P1.0
T2EX, P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
RST
RXD, P3.0
TXD, P3.1
INT0, P3.2
INT1, P3.3
T0, P3.4
T1, P3.5
WR, P3.6
RD, P3.7
XTAL2
XTAL1
VSS
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
VDD
40
39
38
37
36
35
34
33
32
31
30
29
28
27
26
25
24
23
22
21
P0.0, AD0
P0.1, AD1
P0.2, AD2
P0.3, AD3
P0.4, AD4
P0.5, AD5
P0.6, AD6
P0.7, AD7
EA
ALE
PSEN
P2.7, A15
P2.6, A14
P2.5, A13
P2.4, A12
P2.3, A11
P2.2, A10
P2.1, A9
P2.0, A8
44-pin PLCC (W78E365P)
T
2
E
X
,
P P P P
1 1 1 1
. . . .
4 3 2 1
P1.5
P1.6
P1.7
RST
RXD, P3.0
INT2, P4.3
TXD, P3.1
INT0, P3.2
INT1, P3.3
T0, P3.4
T1, P3.5
T
2
,
P
1
.
0
/
I
N
A
T
D
3
0
.
,
P
P
4 V 0
. D .
2 D 0
A
D
1
,
P
0
.
1
A
D
2
,
P
0
.
2
A
D
3
,
P
0
.
3
6 5 4 3 2 1 44 43 42 41 40
7
39
38
8
37
9
36
10
35
11
34
12
33
13
32
14
31
15
30
16
29
17
18 19 20 21 22 23 24 25 26 27 28
P
3
.
6
,
/
W
R
P
3
.
7
,
/
R
D
X
T
A
L
2
X V P P
T S 4 2
A S . .
L
0 0
1
,
A
8
-2-
P
2
.
1
,
A
9
P
2
.
2
,
A
1
0
P
2
.
3
,
A
1
1
P
2
.
4
,
A
1
2
P0.4, AD4
P0.5, AD5
P0.6, AD6
P0.7, AD7
EA
P4.1
ALE
PSEN
P2.7, A15
P2.6, A14
P2.5, A13
Preliminary W78E365
48-Pin LQFP (W78E365D)
P
4
.
6
P1.5
P1.6
P1.7
RST
RXD, P3.0
INT2,P4.3
TXD, P3.1
INT0, P3.2
INT1, P3.3
T0, P3.4
T1, P3.5
P4.7
P
1
.
3
P
1
.
4
P
1
.
2
T
2
E
X
.
P
1
.
1
T
2
.
P
1
.
0
/
I
N
T
3
.
P
4
.
2
V
D
D
A
D
0
.
P
0
.
0
A
D
1
.
P
0
.
1
A
D
2
.
P
0
.
2
A
D
3
.
P
0
.
3
48 47 46 45 44 43 42 41 40 39 38 37
36
35
34
3
33
4
32
5
31
6
30
7
29
8
28
9
27
10
26
11
25
12
13 14 15 16 17 18 19 20 21 22 23 24
1
2
P
3
.
6
,
/
W
R
P
3
.
7
,
/
R
D
X
T
A
L
2
X
T
A
L
1
V P
S 4
S .
0
P
2
.
0
,
A
8
P
2
.
1
,
A
9
P
2
.
2
,
A
1
0
P
2
.
3
,
A
1
1
P
2
.
4
,
A
1
2
P4.5
P0.4, AD4
P0.5, AD5
P0.6, AD6
P0.7, AD7
EA
P4.1
ALE
PSEN
P2.7, A15
P2.6, A14
P2.5, A13
P
4
.
4
44-Pin PQFP (W78E365F)
P
1
.
4
P1.5
P1.6
P1.7
RST
RXD, P3.0
INT2,P4.3
TXD, P3.1
INT0, P3.2
INT1, P3.3
T0, P3.4
T1, P3.5
P
1
.
3
P
1
.
2
T
2
E
X
.
P
1
.
1
/
I
N
T T
2 3
. .
P P
1 4
. .
0 2
V
D
D
A
D
0
.
P
0
.
0
A
D
1
.
P
0
.
1
A
D
2
.
P
0
.
2
A
D
3
.
P
0
.
3
44 43 42 41 40 39 38 37 36 35 34
33
32
3
31
4
30
29
5
28
6
7
27
8
26
9
25
10
24
11
23
12 13 14 15 16 17 18 19 20 21 22
1
2
P
3
.
6
,
/
W
R
P
3
.
7
,
/
R
D
X
T
A
L
2
X
T
A
L
1
V P
S 4
S .
0
P
2
.
0
,
A
8
-3-
P
2
.
1
,
A
9
P
2
.
2
,
A
1
0
P
2
.
3
,
A
1
1
P0.4, AD4
P0.5, AD5
P0.6, AD6
P0.7, AD7
EA
P4.1
ALE
PSEN
P2.7, A15
P2.6, A14
P2.5, A13
P
2
.
4
,
A
1
2
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
PIN DESCRIPTION
SYMBOL
TYPE
DESCRIPTIONS
I
EXTERNAL ACCESS ENABLE: This pin forces the processor to execute the
external ROM. The ROM address and data will not be presented on the bus if
the EA pin is high and the program counter is within the 64 KB area.
PSEN
O H
PROGRAM STORE ENABLE: PSEN enables the external ROM data in the
Port 0 address/data bus. When internal ROM access is performed, no PSEN
strobe signal outputs originate from this pin.
ALE
O H
ADDRESS LATCH ENABLE: ALE is used to enable the address latch that
separates the address from the data on Port 0. ALE runs at 1/6th of the
oscillator frequency. An ALE pulse is omitted during external data memory
accesses.
RST
I L
RESET: A high on this pin for two machine cycles while the oscillator is
running resets the device.
EA
XTAL1
I
CRYSTAL 1: This is the crystal oscillator input. This pin may be driven by an
external clock.
XTAL2
O
CRYSTAL 2: This is the crystal oscillator output. It is the inversion of XTAL1.
VSS
I
GROUND: ground potential.
VDD
I
POWER SUPPLY: Supply voltage for operation.
P0.0−P0.7
I/O D PORT 0: Function is the same as that of standard 8052. (Default)
PORT 0 can be programming configured to standard port with internal pull-ups
P1.0−P1.7
I/O H
PORT 1: Function is the same as that of standard 8052. The ports P1.3~P1.7
also provide alternated function of PWM. See details below.
P2.0−P2.7
I/O H
PORT 2: Port 2 is a bi-directional I/O port with internal pull-ups. This port also
provides the upper address bits for accesses to external memory.
P3.0−P3.7
I/O H
PORT 3: Function is the same as that of the standard 8052.
P4.0−P4.7
I/O H
PORT 4: A bi-directional I/O port with alternate function.
P4.4~P4.7 are direct LED drive outputs (20 mA) and are available on 48-pin
LQFP package
* Note : TYPE I: input, O: output, I/O: bi-directional, H: pull-high, L: pull-low, D: open drain
Port 4
Port 4, SFR P4 at address D8H
-4-
Preliminary W78E365
BLOCK DIAGRAM
P1.0
Port
1
Port 1
Latch
P1.7
ACC
B
Port 0
Interrupt
T1
Latch
T2
Timer
2
Timer
0
P0.0
Port
0
P0.7
DPTR
Stack
Pointer
PSW
ALU
Temp Reg.
Timer
1
PC
Incrementor
UART
Addr. Reg.
P3.0
Port
3
Port 3
P3.7
64KB
SFR RAM
Address
Instruction
Decoder
&
Sequencer
Latch
MTP-ROM
4KB
MTP-ROM
512 bytes
RAM & SFR
P2.0
INT2 / INT3
Port 2
Latch
Bus & Clock
Controller
P4.0
P4.3
Port
4
Port
2
P2.7
Port 4
Latch
Oscillator
XTAL1
XTAL2
Reset Block
ALE
PSEN
RST
-5-
Power control
VCC
Vss
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
FUNCTIONAL DESCRIPTION
The W78E365 architecture consists of a core controller surrounded by various registers, four general
purpose I/O ports, one special purpose programmable 4-bits I/O port, 1K bytes of RAM, three
timer/counters and a serial port. The processor supports 111 different opcodes and references both a
64K program address space and a 64 K data storage space.
RAM
The internal data RAM in the W78E365 is 1K bytes. It is divided into two banks: 256 bytes of
scratchpad RAM and 1K bytes of AUX-RAM. These RAMs are addressed by different ways.
• RAM 0H−7FH can be addressed directly and indirectly as the same as in 8051. Address pointers
are R0 and R1 of the selected register bank.
• RAM 80H−03FFH can only be addressed indirectly as the same as in 8051. Address pointers are
R0, R1 of the selected registers bank.
• AUX-RAM 0H−03FFH is addressed indirectly as the same way to access external data memory
with the MOVX instruction. Address pointer are R0 and R1 of the selected register bank and DPTR
register. An access to external data memory locations higher than 03FFH will be performed with the
MOVX instruction in the same way as in the 8051. The AUX-RAM is disable after a reset. Setting
the bit 4 in CHPCON register will enable the access to AUX-RAM. When AUX-RAM is enabled the
instructions of "MOVX @Ri" will always access to on-chip AUX-RAM. When executing from internal
program memory, an access to AUX-RAM will not affect the Ports P0, P2, WR and RD .
Timers 0, 1, and 2
Timers 0, 1, and 2 each consist of two 8-bit data registers. These are called TL0 and TH0 for Timer 0,
TL1 and TH1 for Timer 1, and TL2 and TH2 for Timer 2. The TCON and TMOD registers provide
control functions for timers 0, 1. The T2CON register provides control functions for Timer 2. RCAP2H
and RCAP2L are used as reload/capture registers for Timer 2.
The operations of Timer 0 and Timer 1 are the same as in the W78C51. Timer 2 is a 16-bit
timer/counter that is configured and controlled by the T2CON register. Like Timers 0 and 1, Timer 2
can operate as either an external event counter or as an internal timer, depending on the setting of bit
C/T2 in T2CON. Timer 2 has three operating modes: capture, auto-reload, and baud rate generator.
The clock speed at capture or auto-reload mode is the same as that of Timers 0 and 1.
INT2 / INT3
Two additional external interrupts, INT2 and INT3 , whose functions are similar to those of external
interrupt 0 and 1 in the standard 80C52. The functions/status of these interrupts are determined/shown
by the bits in the XICON (External Interrupt Control) register. The XICON register is bit-addressable
but is not a standard register in the standard 80C52. Its address is at 0C0H. To set/clear bits in the
XICON register, one can use the "SETB ( CLR ) bit" instruction. For example, "SETB 0C2H" sets the
EX2 bit of XICON.
-6-
Preliminary W78E365
XICON - external interrupt control (C0H)
PX3
EX3
IE3
IT3
PX2
EX2
IE2
IT2
PX3:
External interrupt 3 priority high if set
EX3:
External interrupt 3 enable if set
IE3:
If IT3 = 1, IE3 is set/cleared automatically by hardware when interrupt is detected/serviced
IT3:
External interrupt 3 is falling-edge/low-level triggered when this bit is set/cleared by software
PX2:
External interrupt 2 priority high if set
EX2:
External interrupt 2 enable if set
IE2:
If IT2 = 1, IE2 is set/cleared automatically by hardware when interrupt is detected/serviced
IT2:
External interrupt 2 is falling-edge/low-level triggered when this bit is set/cleared by software
Eight-source interrupt informations:
INTERRUPT SOURCE
External Interrupt 0
Timer/Counter 0
External Interrupt 1
Timer/Counter 1
Serial Port
Timer/Counter 2
External Interrupt 2
External Interrupt 3
VECTOR
ADDRESS
03H
0BH
13H
1BH
23H
2BH
33H
3BH
POLLING
SEQUENCE WITHIN
PRIORITY LEVEL
0 (highest)
1
2
3
4
5
6
7 (lowest)
ENABLE
REQUIRED
SETTINGS
IE.0
IE.1
IE.2
IE.3
IE.4
IE.5
XICON.2
XICON.6
INTERRUPT
TYPE
EDGE/LEVEL
TCON.0
TCON.2
XICON.0
XICON.3
Clock
The W78E365 is designed to be used with either a crystal oscillator or an external clock. Internally, the
clock is divided by two before it is used by default. This makes the W78E365 relatively insensitive to
duty cycle variations in the clock.
Crystal Oscillator
The W78E365 incorporates a built-in crystal oscillator. To make the oscillator work, a crystal must be
connected across pins XTAL1 and XTAL2. In addition, a load capacitor must be connected from each
pin to ground, and a resistor must also be connected from XTAL1 to XTAL2 to provide a DC bias when
the crystal frequency is above 24 MHz.
External Clock
An external clock should be connected to pin XTAL1. Pin XTAL2 should be left unconnected. The
XTAL1 input is a CMOS-type input, as required by the crystal oscillator. As a result, the external clock
signal should have an input one level of greater than 3.5 volts.
-7-
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Power Management
Idle Mode
The idle mode is entered by setting the IDL bit in the PCON register. In the idle mode, the internal
clock to the processor is stopped. The peripherals and the interrupt logic continue to be clocked. The
processor will exit idle mode when either an interrupt or a reset occurs.
Power-down Mode
When the PD bit in the PCON register is set, the processor enters the power-down mode. In this mode
all of the clocks are stopped, including the oscillator. To exit from power-down mode is by a hardware
reset or external interrupts INT0 to INT3 when enabled and set to level triggered.
Reduce EMI Emission
The W78E365 allows user to diminish the gain of on-chip oscillator amplifier by using programmer to
clear the B7 bit of security register. Once B7 is set to 0, a half of gain will be decreased. Care must be
taken if user attempts to diminish the gain of oscillator amplifier, reducing a half of gain may affect the
external crystal operating improperly at high frequency above 24 MHz. The value of R and C1,C2 may
need some adjustment while running at lower gain.
Reset
The external RESET signal is sampled at S5P2. To take effect, it must be held high for at least two
machine cycles while the oscillator is running. An internal trigger circuit in the reset line is used to
deglitch the reset line when the W78E365 is used with an external RC network. The reset logic also
has a special glitch removal circuit that ignores glitches on the reset line. During reset, the ports are
initialized to FFH, the stack pointer to 07H, PCON (with the exception of bit 4) to 00H, and all of the
other SFR registers except SBUF to 00H. SBUF is not reset.
W78E365 Special Function Registers (SFRs) and Reset Values
F8
F0
FF
+B
00000000
CHPENR
00000000
F7
E8
EF
E0
+ACC
00000000
E7
D8
+P4
xxxx1111
DF
D0
+PSW
00000000
D7
C8
+T2CON
00000000
RCAP2L
00000000
RCAP2H
00000000
TL2
00000000
TH2
00000000
C0
XICON
00000000
P4CONA
00000000
P4CONB
00000000
SFRAL
00000000
SFRAH
00000000
B8
+IP
00000000
-8-
CF
SFRFD
00000000
SFRCN
00000000
C7
CHPCON
0xx00000
BF
Preliminary W78E365
W78E365 Special Function Registers (SFRs) and Reset Values, continued
B0
+P3
00000000
P43AL
00000000
P43AH
00000000
A8
+IE
00000000
P42AL
00000000
P42AH
00000000
A0
+P2
11111111
98
+SCON
00000000
90
+P1
11111111
88
+TCON
00000000
80
B7
P2ECON
0000xx00
AF
A7
SBUF
xxxxxxxx
TMOD
00000000
P2EAL
00000000
TL0
00000000
TL1
00000000
P2EAH
00000000
9F
P41AL
00000000
P41AH
00000000
97
TH0
00000000
TH1
00000000
8F
+P0
SP
DPL
DPH
P40AL
P40AH
PCON
11111111
00000111
00000000
00000000
00000000
00000000
00110000
87
Note: 1.The SFRs marked with a plus sign(+) are both byte- and bit-addressable.
2. The text of SFR with bold type characters are extension function registers.
P4CONB (C3H)
BIT
7, 6
NAME
P43FUN1
P43FUN0
5, 4
P43CMP1
P43CMP0
3, 2
P42FUN1
P42FUN0
P42CMP1
P42CMP0
1, 0
FUNCTION
00: Mode 0. P4.3 is a general purpose I/O port which is the same as Port1.
01: Mode 1. P4.3 is a Read Strobe signal for chip select purpose. The address
range depends on the SFR P43AH, P43AL, P43CMP1 and P43CMP0.
10: Mode 2. P4.3 is a Write Strobe signal for chip select purpose. The address
range depends on the SFR P43AH, P43AL, P43CMP1 and P43CMP0.
11: Mode 3. P4.3 is a Read/Write Strobe signal for chip select purpose. The
address range depends on the SFR P43AH, P43AL, P43CMP1, and
P43CMP0.
Chip-select signals address comparison:
00: Compare the full address (16 bits length) with the base address register
P43AH, P43AL.
01: Compare the 15 high bits (A15−A1) of address bus with the base address
register P43AH, P43AL.
10: Compare the 14 high bits (A15−A2) of address bus with the base address
register P43AH, P43AL.
11: Compare the 8 high bits (A15−A8) of address bus with the base address
register P43AH, P43AL.
The P4.2 function control bits which are the similar definition as P43FUN1,
P43FUN0.
The P4.2 address comparator length control bits which are the similar definition
as P43CMP1, P43CMP0.
-9-
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
P4CONA (C2H)
BIT
NAME
7, 6
P41FUN1
P41FUN0
P41CMP1
P41CMP0
P40FUN1
P40FUN0
P40CMP1
P40CMP0
5, 4
3, 2
1, 0
FUNCTION
The P4.1 function control bits which are the similar definition as P43FUN1,
P43FUN0.
The P4.1 address comparator length control bits which are the similar definition
as P43CMP1, P43CMP0.
The P4.0 function control bits which are the similar definition as P43FUN1,
P43FUN0.
The P4.0 address comparator length control bits which are the similar definition
as P43CMP1, P43CMP0.
Port 4 Base Address Registers
P40AH, P40AL:
The Base address register for comparator of P4.0. P40AH contains the high-order byte of address,
P40AL contains the low-order byte of address.
P41AH, P41AL:
The Base address register for comparator of P4.1. P41AH contains the high-order byte of address,
P41AL contains the low-order byte of address.
P42AH, P42AL:
The Base address register for comparator of P4.2. P42AH contains the high-order byte of address,
P42AL contains the low-order byte of address.
P43AH, P43AL:
The Base address register for comparator of P4.3. P43AH contains the high-order byte of address,
P43AL contains the low-order byte of address.
The SFR for Port 4
P4 (D8H)
BIT
7
6
5
4
3
2
1
0
NAME
P43
P42
P41
P40
FUNCTION
Reserve
Reserve
Reserve
Reserve
Port 4 Data bit which outputs to pin P4.3 at mode 0.
Port 4 Data bit. which outputs to pin P4.2 at mode 0.
Port 4 Data bit. which outputs to pin P4.1at mode 0.
Port 4 Data bit which outputs to pin P4.0 at mode 0.
- 10 -
Preliminary W78E365
Here is an example to program the P4.0 as a write strobe signal at the I/O port address 1234H−1237H
and positive polarity, and P4.1−P4.3 are used as general I/O ports.
MOV P40AH,#12H
MOV P40AL,#34H
; Define the base I/O address 1234H for P4.0 as an special function
; pin
MOV P4CONA,#00001010B
; Define the P4.0 as a write strobe signal pin and the comparator
; length ;is 14
MOV P4CONB,#00H
; P4.1−P4.3 as general I/O port which are the same as PORT1
MOV P2ECON,#10H
; Write the P40SINV = 1 to inverse the P4.0 write strobe polarity
; default is negative.
MOV CHPENR,#00H
; Disable CHPCON write attribute.
Then any instruction MOVX @DPTR,A (with DPTR = 1234H−1237H) will generate the positive polarity
write strobe signal at pin P4.0. And the instruction MOV P4,#XX will output the bit3 to bit1 of data #XX
to pin P4.3−P4.1.
PORT 2 OUTPUT DATA BUS
INTERNAL DATA BUS
PORT 2
74373
WRITE
MUX
Latch
G
ADDRESS BUS
EQUAL
16 Bit
comparator
REGISTER
P2EAL
P2EAH
74244
Buffer
DEMUX
G
READ
PORT2 INPUT DATA BUS
P2ECON.P2CN0
P2ECON.P2CN1
PORT2 BASIC STRUCTURE
- 11 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
P2EAH, P2EAL:
The Port Enable Address Registers for Port2 as an Input Buffer/Output-Latched Port.
The I/O port enable address is need to assign when Port2 is defined as input buffer like a 74244, or a
output-latched logic like a 74373. The P2EAH contains the high-order byte of address, the P2EAL
contains the low-order byte of address. The following example shows how to program the Port 2 as a
output-latched port at address 5678H.
MOV P2EAL,#78H
; High-order byte of address to enable Port2 latch function.
MOV P2EAH,#56H
; Low-order byte of address to enable Port2 latch function.
MOV P2ECON,#02H
; Configure the Port2 as an output-latched port.
MOV DPTR,#5678H
; Move data 5678H to DPTR.
MOV A, #55H
MOVX @DPTR, A
; The pins P2.7−P2.0 will output and latch the value 55H.
When Port2 is configured as 74244 or 74373 function, the instruction " MOV P2,#XX " will write the
data #XX to P2 register only but not output to port pins P2.7−P2.0.
Port 2 Expanded Control Register(P2ECON).
P2ECON (AEH)
BIT
7
6
5
4
3
2
1, 0
NAME
FUNCTION
P43CSINV The active polarity of P4.3 when pin P4.3 is defined as read and/or write strobe
signal.
= 1 : P4.3 is active high when pin P4.3 is defined as read and/or write strobe
signal.
= 0 : P4.3 is active low when pin P4.3 is defined as read and/or write strobe
signal.
P42CSINV The similarity definition as P43SINV.
P41CSINV The similarity definition as P43SINV.
P40CSINV The similarity definition as P43SINV.
Reserve
Reserve
P2CN1,
00 : Pins P2.7−P2.0 is the standard 8051 Port 2.
P2CN0
01 : Pins P2.7−P2.0 is input buffer port which the port enable address
depends on the content of P2EAL and P2EAH
10 : Pins P2.7−P2.0 is output-latched port which the port enable address
depends on the content of P2EAL and P2EAH.
11 : Undefined.
- 12 -
Preliminary W78E365
P4xCSINV
P4 REGISTER
P4.x
DATA I/O
RD_CS
MUX 4->1
WR_CS
READ
WRITE
RD/WR_CS
PIN
P4.x
ADDRESS BUS
P4xFUN0
P4xFUN1
EQUAL
REGISTER
P4xAL
P4xAH
Bit Length
Selectable
comparator
P4.x INPUT DATA BUS
REGISTER
P4xCMP0
P4xCMP1
Port 4 Block Diagram
In-System Programming (ISP) Mode
The W78E365 equips one 64K byte of main FLASH EPROM bank for application program (called
APROM) and one 4K byte of auxiliary FLASH EPROM bank for loader program (called LDROM). In the
normal operation, the microcontroller executes the code in the APROM. If the content of APROM
needs to be modified, the W78E365 allows user to activate the In-System Programming (ISP) mode by
setting the CHPCON register. The CHPCON is read-only by default, software must write two
specific values 87H, then 59H sequentially to the CHPENR register to enable the CHPCON write
attribute. Writing CHPENR register with the values except 87H and 59H will close CHPCON
register write attribute. The W78E365 achieves all in-system programming operations including
enter/exit ISP Mode, program, erase, read ...etc, during device in the idle mode. Setting the bit
CHPCON.0 the device will enter in-system programming mode after a wake-up from idle mode.
Because device needs proper time to complete the ISP operations before awaken from idle mode,
software may use timer interrupt to control the duration for wake-up from idle mode. This in-system
programming feature makes the job easy and efficient in which the application needs to update
firmware frequently. In some applications, the in-system programming feature make it possible that
the end-user is able to easily update the system firmware by themselves without opening the chassis.
- 13 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
SFRAH,SFRAL:
The objective address of on-chip FLASH EPROM in the in-system programming mode. SFRFAH
contains the high-order byte of address, SFRFAL contains the low-order byte of address.
SFRFD:
The programming data for on-chip FLASH EPROM in programming mode.
SFRCN:
The control byte of on-chip FLASH EPROM programming mode.
SFRCN (C7)
BIT
NAME
7
-
6
WFWIN
FUNCTION
Reserve.
On-chip FLASH EPROM bank select for in-system programming.
= 0 : 64K bytes FLASH EPROM bank is selected as destination for reprogramming.
= 1 : 4K bytes FLASH EPROM bank is selected as destination for reprogramming.
5
OEN
FLASH EPROM output enable.
4
CEN
FLASH EPROM chip enable.
3, 2,
CTRL[3:0] The flash control signals
1, 0
Mode
WFWIN
CTRL<3:0>
OEN
CEN
SFRAH,SFRAL
SFRFD
Erase 64 KB APROM
0
0010
1
0
X
X
Program 64 KB APROM
0
0001
1
0
Address in
Data in
Read 64 KB APROM
0
0000
0
0
Address in
Data out
Erase 4 KB LDROM
1
0010
1
0
X
X
Program 4 KB LDROM
1
0001
1
0
Address in
Data in
Read 4 KB LDROM
1
0000
0
0
Address in
Data out
- 14 -
Preliminary W78E365
In-System Programming Control Register (CHPCON)
CHPCON (BFH)
BIT
7
NAME
SWRESET
(F04KMODE)
FUNCTION
When this bit is set to 1, and both FBOOTSL and FPROGEN are set to 1. It
will enforce microcontroller reset to initial condition just like power on reset.
This action will re-boot the microcontroller and start to normal operation. To
read this bit in logic-1 can determine that the F04KBOOT mode is running.
6
-
Reserve.
5
-
Reserve.
4
ENAUXRAM
1: Enable on-chip AUX-RAM.
0: Disable the on-chip AUX-RAM
3
0
must set to 0.
2
0
must set to 0.
1
FBOOTSL
The Program Location Select.
0: The Loader Program locates at the 64 KB APROM. 4 KB LDROM is
destination for re-programming.
1: The Loader Program locates at the 4 KB memory bank. 64 KB APROM is
destination for re-programming.
0
FPROGEN
FLASH EPROM Programming Enable.
= 1:enable. The microcontroller enter the in-system programming mode after
entering the idle mode and wake-up from interrupt. During in-system
programming mode, the operation of erase, program and read are acheived
when device enters idle mode.
= 0 0:disable. The on-chip flash memory is read-only. In-system
programmability is disabled.
F04KBOOT Mode (Boot From LDROM )
By default, the W78E365 boots from APROM program after a power on reset. On some occasions,
user can force the W78E365 to boot from the LDROM program via following settings. The possible
situation that you need to enter F04KBOOT mode is when the APROM program can not run properly
and device can not jump back to LDROM to execute in-system programming function. Then you can
use this F04KBOOT mode to force the W78E365 jumps to LDROM and excutes in-system
programming procedure. When you design your system, you may reserve the pins P2.6, P2.7 to
switches or jumpers. For example in a CD-ROM system, you can connect the P2.6 and P2.7 to PLAY
and EJECT buttons on the panel. When the APROM program fails to execute the normal application
program. User can press both two buttons at the same time and then turn on the power of the personal
computer to force the W78E365 to enter the F04KBOOT mode. After power on of personal computer,
you can release both buttons and finish the in-system programming procedure to update the APROM
code. In application system design, user must take care of the P2, P3, ALE, EA and PSEN pin value
at reset to prevent from accidentally activating the programming mode or F04KBOOT mode.
- 15 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
F04KBOOT MODE
P4.3
P2.7
P2.6
Mode
X
L
L
FO4KBOOT
L
X
X
FO4KBOOT
The Reset Timing For Entering
F04KBOOT Mode
P2.7
Hi-Z
P2.6
Hi-Z
RST
30 mS
10 mS
- 16 -
Preliminary W78E365
The Algorithm of In-System Programming
Part 1:64KB APROM
START
procedure of entering
In-System Programming Mode
Enter In-System
Programming Mode ?
(conditions depend on
user's application)
No
Yes
Setting control registers
MOV CHPENR,#87H
MOV CHPENR,#59H
MOV CHPCON,#03H
Execute the normal application
program
Setting Timer (about 1.5us)
and enable timer interrupt
END
Start Timer and enter idle Mode.
( CPU will be wakened from idle mode
by timer interrupt, then enter In-System
Programming mode)
CPU will be wakened by interrupt and
re-boot from 4KB LDROM to execute
the loader program.
Go
- 17 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Part 2: 4KB LDROM
Procedure of Updating
the 64KB APROM
Go
Timer Interrupt Service Routine:
Stop Timer & disable interrupt
PGM
Is F04KBOOT Mode?
(CHPCON.7=1)
Yes
Yes
End of Programming ?
No
No
Reset the CHPCON Register:
MOV CHPENR,#87H
MOV CHPENR,#59H
MOV CHPCON,#03H
Setting Timer and enable Timer
interrupt for wake-up .
(150us for program operation)
Yes
Is currently in the
F04KBOOT Mode ?
No
Setting Timer and enable Timer
interrupt for wake-up .
(15ms for erasing operation)
Setting erase operation mode:
MOV SFRCN,#22H
(Erase 64KB APROM)
Start Timer and enter IDLE
Mode.
(Erasing...)
Get the parameters of new code
(Address and data bytes)
through I/O ports, UART or
other interfaces.
Software reset CPU and
re-boot from the 64KB
APROM.
MOV CHPENR,#87H
MOV CHPENR,#59H
MOV CHPCON,#83H
Setting control registers for
programming:
MOV SFRAH,#ADDRESS_H
MOV SFRAL,#ADDRESS_L
MOV SFRFD,#DATA
MOV SFRCN,#21H
End of erase
operation. CPU will
be wakened by Timer
interrupt.
Hardware Reset to re-boot
from new 64KB
APROM. (S/W reset is
invalid in F04KBOOT
Mode)
END
Executing new code from address
00H in the 64KB APROM.
PGM
- 18 -
Preliminary W78E365
Security
During the on-chip FLASH EPROM programming mode, the FLASH EPROM can be programmed and
verified repeatedly. Until the code inside the FLASH EPROM is confirmed OK, the code can be
protected. The protection of FLASH EPROM and those operations on it are described below.
The W78E365 has several Special Setting Registers, including the Security Register and
Company/Device ID Registers, which can not be accessed in programming mode. Those bits of the
Security Registers can not be changed once they have been programmed from high to low. They can
only be reset through erase-all operation. The contents of the Company ID and Device ID registers
have been set in factory. The Security Register is located at the 0FFFFH of the LDROM space.
D7 D6 D5 D4 D3 D2 D1 D0
B7 Reserved
B2 B1 B0
4KB Flash EPROM
Security Bits
Program Memory
LDROM
B0: Lock bit, logic 0: active
B1: MOVC inhibit,
logic 0: the MOVC instruction in external memory
cannot access the code in internal memory.
logic 1: no restriction.
0000h
0FFFh
64KB Flash EPROM
Program Memory
APROM
Reserved
Reserved
B2: Encryption
logic 0: the encryption logic enable
logic 1: the encryption logic disable
B07: Osillator Control
logic 0: 1/2 gain
logic 1: Full gain
Default 1 for all security bits.
Reserved bits must be kept in logic 1.
Security Register
FFFFh
Special Setting Register
Lock bit
This bit is used to protect the customer's program code in the W78E365. It may be set after the
programmer finishes the programming and verifies sequence. Once this bit is set to logic 0, both the
FLASH EPROM ROM data and Special Setting Registers can not be accessed again.
MOVC Inhibit
This bit is used to restrict the accessible region of the MOVC instruction. It can prevent the MOVC
instruction in external program memory from reading the internal program code. When this bit is set to
logic 0, a MOVC instruction in external program memory space will be able to access code only in the
external memory, not in the internal memory. A MOVC instruction in internal program memory space
will always be able to access the ROM data in both internal and external memory. If this bit is logic 1,
there are no restrictions on the MOVC instruction.
- 19 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Encryption
This bit is used to enable/disable the encryption logic for code protection. Once encryption feature is
enabled, the data presented on port 0 will be encoded via encryption logic. Only whole chip erase will
reset this bit.
Oscillator Control
W78E365 allow user to diminish the gain of on-chip oscillator amplifier by using programmer to set the
bit B7 of security register. Once B7 is set to 0, a half of gain will be decreased. Care must be taken if
user attempts to diminish the gain of oscillator amplifier, reducing a half of gain may improperly affect
the external crystal operation at high frequency above 24 MHz. The value of R and C1,C2 may need
some adjustment while running at lower gain.
ABSOLUTE MAXIMUM RATINGS
ITEM
1
2
3
4
SYMBOL
VDD−VSS
VIN
TA
TST
PARAMETER
DC Power Supply
Input Voltage
Operating Temperature
Storage Temperature
MIN.
-0.3
VSS -0.3
0
-55
MAX.
+6.0
VDD +0.3
70
+150
UNIT
V
V
°C
°C
Note: Exposure to conditions beyond those listed under Absolute Maximum Ratings may adversely affect the life and reliability
of the device.
D.C. ELECTRICAL CHARACTERISTICS
(VDD-VSS = 5V±10%, TA = 25 °C, Fosc = 20 MHz, unless otherwise specified.)
SYMBOL
PARAMETER
SPECIFICATION
MIN.
MAX.
TEST CONDITIONS
UNIT
VDD
Operating Voltage
4.5
5.5
V
IDD
Operating Current
-
20
mA
RST = 1, P0 = VDD
No load
VDD = 5.5V
IIDLE
Idle Current
-
6
mA
Idle mode
VDD = 5.5V
IPWDN
Power Down Current
-
50
µA
Power-down mode
VDD = 5.5V
IIN1
Input Current
-50
+10
µA
P1, P2, P3, P4
IIN2
Input Current RST
VDD = 5.5V
VIN = 0V or VDD
-10
+300
µA
VDD = 5.5V
0<VIN<VDD
- 20 -
Preliminary W78E365
D.C. Electrical characteristics, continued
SYMBOL
VIL1
PARAMETER
Input Low Voltage
SPECIFICATION
TEST CONDITIONS
MIN.
MAX.
UNIT
0
0.8
V
VDD = 4.5V
P0, P1, P2, P3, P4, EA
VIL2
Input Low Voltage RST
0
0.8
V
VDD = 4.5V
VIL3
Input Low Voltage
0
0.8
V
VDD = 4.5V
2.4
VDD+0.2
V
VDD = 5.5V
[*4]
XTAL1
VIH1
Input High Voltage
P0, P1, P2, P3, P4, EA
VIH2
Input High Voltage RST
3.5
VDD+0.2
V
VDD = 5.5V
VIH3
Input High Voltage
3.5
VDD+0.2
V
VDD = 5.5V
-
0.45
V
VDD = 4.5V
-
0.45
V
[*4]
XTAL1
VOL1
Output Low Voltage
IOL = +2 mA
P1, P2, P3, P4
VOL2
Output Low Voltage
P0, ALE, PSEN
Isk1
IOL = +4 mA
[*3]
Sink current P1, P3, P4
VDD = 4.5V
4
12
mA
VDD = 4.5V
Vin = 0.45V
Isk2
10
Sink current
20
mA
Vin = 0.45V
P0, P2, ALE, PSEN
VOH1
Output High Voltage
2.4
-
V
Output High Voltage
P0, ALE, PSEN
Isr1
2.4
-
V
Source current
Source current
VDD = 4.5V
IOH = -400 µA
[*3]
-120
-250
µA
P1, P2, P3, P4
Isr2
VDD = 4.5V
IOH = -100 µA
P1, P2, P3, P4
VOH2
VDD = 4.5V
VDD = 4.5V
Vin = 2.4V
-8
-20
mA
VDD = 4.5V
Vin = 2.4V
P0, P2, ALE, PSEN
Notes:
*1. RST pin is a Schmitt trigger input.
*3. P0, ALE and /PSEN are tested in the external access mode.
*4. XTAL1 is a CMOS input.
*5. Pins of P1, P2, P3 , P4 can source a transition current when they are being externally driven from 1 to 0. The transition
current reaches its maximum value when VIN approximates to 2V.
- 21 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
AC CHARACTERISTICS
The AC specifications are a function of the particular process used to manufacture the part, the ratings
of the I/O buffers, the capacitive load, and the internal routing capacitance. Most of the specifications
can be expressed in terms of multiple input clock periods (TCP), and actual parts will usually
experience less than a ¡Ó20 nS variation. The numbers below represent the performance expected
from a 0.6 micron CMOS process when using 2 and 4 mA output buffers.
Clock Input Waveform
XTAL1
TCH
TCL
F OP,
PARAMETER
TCP
SYMBOL
MIN.
TYP.
MAX.
UNIT
NOTES
Operating Speed
FOP
0
-
40
MHz
1
Clock Period
TCP
25
-
-
nS
2
Clock High
TCH
10
-
-
nS
3
Clock Low
TCL
10
-
-
nS
3
Notes:
1. The clock may be stopped indefinitely in either state.
2. The TCP specification is used as a reference in other specifications.
3. There are no duty cycle requirements on the XTAL1 input.
- 22 -
Preliminary W78E365
Program Fetch Cycle
PARAMETER
SYMBOL
MIN.
TYP.
MAX.
UNIT
NOTES
Address Valid to ALE Low
TAAS
1 TCP-∆
-
-
nS
4
Address Hold from ALE Low
TAAH
1 TCP-∆
-
-
nS
1, 4
ALE Low to PSEN Low
TAPL
1 TCP-∆
-
-
nS
4
PSEN Low to Data Valid
TPDA
-
-
2 TCP
nS
2
Data Hold after PSEN High
TPDH
0
-
1 TCP
nS
3
Data Float after PSEN High
TPDZ
0
-
1 TCP
nS
ALE Pulse Width
TALW
2 TCP-∆
2 TCP
-
nS
4
PSEN Pulse Width
TPSW
3 TCP-∆
3 TCP
-
nS
4
Notes:
1. P0.0−P0.7, P2.0−P2.7 remain stable throughout entire memory cycle.
2. Memory access time is 3 TCP.
3. Data have been latched internally prior to PSEN going high.
4. "∆" (due to buffer driving delay and wire loading) is 20 nS.
Data Read Cycle
PARAMETER
SYMBOL
MIN.
TYP.
MAX.
UNIT
NOTES
ALE Low to RD Low
TDAR
3 TCP-∆
-
3 TCP+∆
nS
1, 2
RD Low to Data Valid
TDDA
-
-
4 TCP
nS
1
Data Hold from RD High
TDDH
0
-
2 TCP
nS
Data Float from RD High
TDDZ
0
-
2 TCP
nS
RD Pulse Width
TDRD
6 TCP-∆
6 TCP
-
nS
2
Notes:
1. Data memory access time is 8 TCP.
2. "∆" (due to buffer driving delay and wire loading) is 20 nS.
- 23 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Data Write Cycle
ITEM
SYMBOL
MIN.
TYP.
MAX.
UNIT
ALE Low to WR Low
TDAW
3 TCP-∆
-
3 TCP+∆
nS
Data Valid to WR Low
TDAD
1 TCP-∆
-
-
nS
Data Hold from WR High
TDWD
1 TCP-∆
-
-
nS
WR Pulse Width
TDWR
6 TCP-∆
6 TCP
-
nS
Note: "∆" (due to buffer driving delay and wire loading) is 20 nS.
Port Access Cycle
PARAMETER
SYMBOL
MIN.
TYP.
MAX.
UNIT
Port Input Setup to ALE Low
TPDS
1 TCP
-
-
nS
Port Input Hold from ALE Low
TPDH
0
-
-
nS
Port Output to ALE
TPDA
1 TCP
-
-
nS
Note: Ports are read during S5P2, and output data becomes available at the end of S6P2. The timing data are referenced
to ALE, since it provides a convenient reference.
TIMING WAVEFORMS
Program Fetch Cycle
S1
S2
S3
S4
S5
S6
S1
S2
S3
S4
S5
XTAL1
TALW
ALE
TAPL
PSEN
TPSW
TAAS
PORT 2
TPDA
TAAH
TPDH,
TPDZ
PORT 0
Code
A0-A7
Data
A0-A7
- 24 -
Code
A0-A7
Data
A0-A7
S6
Preliminary W78E365
Data Read Cycle
S4
S5
S6
S1
S2
S3
S4
S5
S6
S1
S2
S3
XTAL1
ALE
PSEN
PORT 2
A8-A15
DATA
A0-A7
PORT 0
TDAR
TDDA
T DDH, TDDZ
RD
TDRD
Data Write Cycle
S4
S5
S6
S1
S2
S3
S4
S5
S6
S1
S2
S3
XTAL1
ALE
PSEN
PORT 2
PORT 0
A8-A15
A0-A7
DATA OUT
TDWD
TDAD
WR
TDAW
TDWR
- 25 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Port Access Cycle
S5
S6
S1
XTAL1
ALE
TPDS
TPDA
TPDH
DATA OUT
PORT
INPUT
SAMPLE
- 26 -
Preliminary W78E365
TYPICAL APPLICATION CIRCUIT
Expanded External Program Memory and Crystal
VDD
VDD
35
EA
21
10 u
XTAL1
R 22
XTAL2
CRYSTAL
8.2 K
10 RST
C1
C2
INT0
14
15
16
17
INT1
T0
T1
2
3
4
5
6
7
8
9
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P0.0
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
P0.7
43 AD0
42 AD1
41 AD2
40 AD3
39 AD4
38 AD5
37 AD6
36 AD7
AD0 3
AD1 4
AD2 7
AD3 8
AD413
AD514
AD617
AD718
P2.0
P2.1
P2.2
P2.3
P2.4
P2.5
P2.6
P2.7
24
25
26
27
28
29
30
31
GND 1
OC
11 G
RD
WR
PSEN
ALE
TXD
RXD
19
18
32
33
13
11
A8
A9
A10
A11
A12
A13
A14
A15
D0
D1
D2
D3
D4
D5
D6
D7
Q0
Q1
Q2
Q3
Q4
Q5
Q6
Q7
2 A0
5 A1
6 A2
9 A3
12 A4
15 A5
16 A6
19 A7
74LS373
A0 10
A1 9
A2 8
A3 7
A4 6
A5 5
A6 4
A7 3
A8 25
A9 24
A10 21
A11 23
A12 2
A13 26
A14 27
A15 1
A0
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
A13
A14
A15
O0
O1
O2
O3
O4
O5
O6
O7
11
12
13
15
16
17
18
19
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
GND 20 CE
22
OE
2764
W78E62BP
Figure A
CRYSTAL
C1
C2
R
6 MHz
47P
47P
-
16 MHz
30P
30P
-
24 MHz
15P
10P
-
32 MHz
10P
10P
6.8K
40 MHz
5P
5P
4.7K
Above table shows the reference values for crystal applications.
Note1: C1, C2, R components refer to Figure A
Note2: Crystal layout must get close to XTAL1 and XTAL2 pins on user's application board.
- 27 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Expanded External Data Memory and Oscillator
VDD
VDD
35
EA
21
XTAL1
20
XTAL2
10 u OSCILLATOR
8.2 K
10 RST
14
15
16
17
2
3
4
5
6
7
8
9
INT0
INT1
T0
T1
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P0.0
P0.1
P0.2
P0.3
P0.4
P0.5
P0.6
P0.7
43
42
41
40
39
38
37
36
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
P2.0
P2.1
P2.2
P2.3
P2.4
P2.5
P2.6
P2.7
24
25
26
27
28
29
30
31
A8
A9
A10
A11
A12
A13
A14
RD
19
18
32
33
13
11
WR
PSEN
ALE
TXD
RXD
AD0 3
AD1 4
AD2 7
AD3 8
AD4 13
AD5 14
AD6 17
AD7 18
GND 1
D0
D1
D2
D3
D4
D5
D6
D7
Q0
Q1
Q2
Q3
Q4
Q5
Q6
Q7
2
5
6
9
12
15
16
19
OC
11 G
74LS373
A0
A1
A2
A3
A4
A5
A6
A7
A0 10
A1 9
A2 8
A3 7
A4 6
A5 5
A6 4
A7 3
A8 25
A9 24
A10 21
A11 23
A12 2
A13 26
A14 1
A0
A1
A2
A3
A4
A5
A6
A7
A8
A9
A10
A11
A12
A13
A14
GND 20
22
27
CE
OE
WR
20256
W78E62BP
Figure B
- 28 -
D0
D1
D2
D3
D4
D5
D6
D7
11
12
13
15
16
17
18
19
AD0
AD1
AD2
AD3
AD4
AD5
AD6
AD7
Preliminary W78E365
PACKAGE DIMENSIONS
44-pin PLCC
HD
D
6
1
44
40
Symbol
7
A
A1
A2
b1
b
c
D
E
e
GD
GE
HD
HE
L
y
39
HE
E
17
GE
29
18
28
c
Dimension in inch Dimension in mm
Min. Nom. Max. Min. Nom. Max.
0.185
4.699
0.508
0.020
3.683
3.81
3.937
0.66
0.711
0.813
0.406 0.457
0.559
0.145
0.150
0.155
0.026
0.028
0.032
0.016
0.018
0.022
0.008
0.010
0.014
0.203
0.254
0.356
0.648
0.653
0.658 16.46
16.59
16.71
0.648
0.653
0.658 16.46
16.59
16.71
0.050
1.27
BSC
BSC
0.590
0.610
0.630 14.99 15.49
0.590
0.610
0.630 14.99 15.49
16.00
16.00
0.680
0.690
0.700 17.27
17.53
17.78
0.680
0.690
0.700 17.27
17.53
17.78
0.090
0.100
0.110
2.296
2.54
2.794
0.004
0.10
L
Notes:
A2 A
1. Dimension D & E do not include interlead
flash.
2. Dimension b1 does not include dambar
protrusion/intrusion.
3. Controlling dimension: Inches
4. General appearance spec. should be based
on final visual inspection spec.
θ
e
b
b1
Seating Plane
A1
y
GD
48-pin LQFP
HD
D
25
36
Symbol
A
A1
A2
b
c
D
E
e
HD
HE
L
L1
y
0
24
37
E
48
HE
13
1
e
b
12
Dimension in mm
Min. Nom. Max.
---
---
1.60
0.05
---
0.15
1.35
1.40
1.45
0.17
0.20
0.27
0.09
---
0.20
7.00
7.00
0.50
9.00
9.00
0.45
0.60
0.75
1.00
---
0.08
---
0
3.5
7
Notes:
c
A2
Seating Plane
See Detail F
A1
y
A
L
L1
- 29 -
Detail F
1. Dimensions D & E do not include interlead
flash.
2. Dimension b does not include dambar
protrusion/intrusion.
3. Controlling dimension: Millimeters
4. General appearance spec. should be based
on final visual inspection spec.
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
Application Note: In-system Programming Software Examples
This application note illustrates the in-system programmability of the Winbond W78E365 FLASH
EPROM microcontroller. In this example, microcontroller will boot from 64KB APROM bank and waiting
for a key to enter in-system programming mode for re-programming the contents of 64KB APROM.
While entering in-system programming mode, microcontroller excutes the loader program in 4KB
LDROM bank. The loader program erases the 64KB APROM then reads the new code data from
external SRAM buffer (or through other interfaces) to update the 64KB APROM.
EXAMPLE 1:
;*******************************************************************************************************************
;* Example of 64K APROM program: Program will scan the P1.0. if P1.0 = 0, enters in-system
;* programming mode for updating thecontents of APROM code else excutes the current ROM code.
;* XTAL = 40 MHz
;*******************************************************************************************************************
.chip 8052
.RAMCHK OFF
.symbols
CHPCON
CHPENR
SFRAL
SFRAH
SFRFD
SFRCN
EQU
EQU
EQU
EQU
EQU
EQU
BFH
F6H
C4H
C5H
C6H
C7H
ORG
0H
LJMP
100H
;JUMP TO MAIN PROGRAM
;************************************************************************
;* TIMER0 SERVICE VECTOR ORG = 000BH
;************************************************************************
ORG
00BH
CLR
TR0
;TR0 = 0,STOP TIMER0
MOV
TL0,R6
MOV
TH0,R7
RETI
;************************************************************************
;* 64K APROM MAIN PROGRAM
;************************************************************************
ORG
100H
MAIN_64K:
MOV A,P1
ANL A,#01H
CJNE A,#01H,PROGRAM_64K
JMP NORMAL_MODE
;SCAN P1.0
;IF P1.0=0, ENTER IN-SYSTEM PROGRAMMING MODE
- 30 -
Preliminary W78E365
PROGRAM_64K:
MOV CHPENR,#87H
MOV CHPENR,#59H
MOV CHPCON,#03H
MOV TCON,#00H
MOV IP,#00H
MOV IE,#82H
MOV R6,#FEH
MOV R7,#FFH
MOV TL0,R6
MOV TH0,R7
MOV TMOD,#01H
MOV TCON,#10H
MOV PCON,#01H
;CHPENR = 87H, CHPCON REGISTER WRTE ENABLE
;CHPENR = 59H, CHPCON REGISTER WRITE ENABLE
;CHPCON = 03H, ENTER IN-SYSTEM PROGRAMMING MODE
;TR = 0 TIMER0 STOP
;IP = 00H
;TIMER0 INTERRUPT ENABLE FOR WAKE-UP FROM IDLE MODE
;TL0 = FEH
;TH0 = FFH
;TMOD = 01H,SET TIMER0 A 16-BIT TIMER
;TCON = 10H,TR0 = 1,GO
;ENTER IDLE MODE FOR LAUNCHING THE IN-SYSTEM
;PROGRAMMABILITY
;********************************************************************************
;* Normal mode 64KB APROM program: depending user's application
;********************************************************************************
NORMAL_MODE:
.
;User's application program
.
.
.
.
EXAMPLE 2:
;***************************************************************************************************************************** ;*
Example of 4KB LDROM program: This lorder program will erase the 64KB APROM first, then reads the new ;*
code from external SRAM and program them into 64KB APROM bank. XTAL = 40 MHz
;*****************************************************************************************************************************
.chip 8052
.RAMCHK OFF
.symbols
CHPCON
CHPENR
SFRAL
SFRAH
SFRFD
SFRCN
EQU
EQU
EQU
EQU
EQU
EQU
BFH
F6H
C4H
C5H
C6H
C7H
ORG
LJMP
000H
100H
;JUMP TO MAIN PROGRAM
;************************************************************************
;* 1. TIMER0 SERVICE VECTOR ORG = 0BH
;************************************************************************
ORG 000BH
CLR TR0
;TR0 = 0,STOP TIMER0
MOV TL0,R6
MOV TH0,R7
RETI
- 31 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
;************************************************************************
;* 4KB LDROM MAIN PROGRAM
;************************************************************************
ORG 100H
MAIN_4K:
MOV CHPENR,#87H
MOV CHPENR,#59H
MOV A,CHPCON
ANL A,#80H
CJNE A,#80H,UPDATE_64K
;CHPENR = 87H, CHPCON WRITE ENABLE.
;CHPENR = 59H, CHPCON WRITE ENABLE.
;CHECK F04KBOOT MODE ?
MOV CHPCON,#03H
MOV CHPENR,#00H
;CHPCON = 03H, ENABLE IN-SYSTEM PROGRAMMING.
;DISABLE CHPCON WRITE ATTRIBUTE
MOV TCON,#00H
MOV TMOD,#01H
MOV IP,#00H
MOV IE,#82H
MOV R6,#FEH
MOV R7,#FFH
MOV TL0,R6
MOV TH0,R7
MOV TCON,#10H
MOV PCON,#01H
;TCON = 00H ,TR = 0 TIMER0 STOP
;TMOD = 01H ,SET TIMER0 A 16BIT TIMER
;IP = 00H
;IE = 82H, TIMER0 INTERRUPT ENABLED
;TCON = 10H,TR0 = 1,GO
;ENTER IDLE MODE
UPDATE_64K:
MOV CHPENR,#00H
MOV TCON,#00H
MOV IP,#00H
MOV IE,#82H
MOV TMOD,#01H
MOV R6,#3CH
;DISABLE CHPCON WRITE-ATTRIBUTE
;TCON = 00H ,TR = 0 TIM0 STOP
;IP = 00H
;IE = 82H,TIMER0 INTERRUPT ENABLED
;TMOD = 01H ,MODE1
;SET WAKE-UP TIME FOR ERASE OPERATION, ABOUT 15ms.
DEPENDING
;ON USER'S SYSTEM CLOCK RATE.
MOV R7,#B0H
MOV TL0,R6
MOV TH0,R7
ERASE_P_4K:
MOV SFRCN,#22H
MOV TCON,#10H
MOV PCON,#01H
;SFRCN(C7H) = 22H ERASE 64K
;TCON = 10H,TR0 = 1,GO
;ENTER IDLE MODE( FOR ERASE OPERATION)
- 32 -
Preliminary W78E365
;*********************************************************************
;* BLANK CHECK
;*********************************************************************
MOV SFRCN,#0H
MOV SFRAH,#0H
MOV SFRAL,#0H
MOV R6,#FBH
MOV R7,#FFH
MOV TL0,R6
MOV TH0,R7
;READ 64KB APROM MODE
;START ADDRESS = 0H
;SET TIMER FOR READ OPERATION, ABOUT 1.5us.
BLANK_CHECK_LOOP:
SETB TR0
MOV PCON,#01H
MOV A,SFRFD
;ENABLE TIMER 0
;ENTER IDLE MODE
;READ ONE BYTE
CJNE A,#FFH,BLANK_CHECK_ERROR
INC SFRAL
;NEXT ADDRESS
MOV A,SFRAL
JNZ BLANK_CHECK_LOOP
INC SFRAH
MOV A,SFRAH
CJNE A,#0H,BLANK_CHECK_LOOP ;END ADDRESS=FFFFH
JMP PROGRAM_64KROM
BLANK_CHECK_ERROR:
MOV P1,#F0H
MOV P3,#F0H
JMP $
;*******************************************************************************
;* RE-PROGRAMMING 64KB APROM BANK
;*******************************************************************************
PROGRAM_64KROM:
MOV DPTR,#0H
MOV R2,#00H
MOV R1,#00H
;THE ADDRESS OF NEW ROM CODE
;TARGET LOW BYTE ADDRESS
;TARGET HIGH BYTE ADDRESS
MOV DPTR,#0H
MOV SFRAH,R1
MOV SFRCN,#21H
MOV R6,#0CH
MOV R7,#FEH
MOV TL0,R6
MOV TH0,R7
;EXTERNAL SRAM BUFFER ADDRESS
;SFRAH, TARGET HIGH ADDRESS
;SFRCN(C7H) = 21 (PROGRAM 64K)
;SET TIMER FOR PROGRAMMING, ABOUT 150us.
- 33 -
Publication Release Date: April 2001
Revision A1
Preliminary W78E365
PROG_D_64K:
MOV SFRAL,R2
;SFRAL(C4H)= LOW BYTE ADDRESS
MOVX A,@DPTR
;READ DATA FROM EXTERNAL SRAM BUFFER
MOV SFRFD,A
;SFRFD(C6H) = DATA IN
MOV TCON,#10H
;TCON = 10H,TR0 = 1,GO
MOV PCON,#01H
;ENTER IDLE MODE( PRORGAMMING)
INC DPTR
INC R2
CJNE R2,#0H,PROG_D_64K
INC R1
MOV SFRAH,R1
CJNE R1,#0H,PROG_D_64K
;*****************************************************************************
; * VERIFY 64KB APROM BANK
;*****************************************************************************
MOV R4,#03H
;ERROR COUNTER
MOV R6,#FBH
;SET TIMER FOR READ VERIFY, ABOUT 1.5us.
MOV R7,#FFH
MOV TL0,R6
MOV TH0,R7
MOV DPTR,#0H
;The start address of sample code
MOV R2,#0H
;Target low byte address
MOV R1,#0H
;Target high byte address
MOV SFRAH,R1
;SFRAH, Target high address
MOV SFRCN,#00H
;SFRCN = 00 (Read ROM CODE)
READ_VERIFY_64K:
MOV SFRAL,R2
;SFRAL(C4H) = LOW ADDRESS
MOV TCON,#10H
;TCON = 10H,TR0 = 1,GO
MOV PCON,#01H
INC R2
MOVX A,@DPTR
INC DPTR
CJNE A,SFRFD,ERROR_64K
CJNE R2,#0H,READ_VERIFY_64K
INC R1
MOV SFRAH,R1
CJNE R1,#0H,READ_VERIFY_64K
;******************************************************************************
;* PROGRAMMING COMPLETLY, SOFTWARE RESET CPU
;******************************************************************************
MOV CHPENR,#87H
;CHPENR = 87H
MOV CHPENR,#59H
;CHPENR = 59H
MOV CHPCON,#83H
;CHPCON = 83H, SOFTWARE RESET.
ERROR_64K:
DJNZ R4,UPDATE_64K ;IF ERROR OCCURS, REPEAT 3 TIMES.
.
;IN-SYSTEM PROGRAMMING FAIL, USER'S PROCESS TO DEAL WITH IT.
.
.
.
- 34 -
Preliminary W78E365
Headquarters
Winbond Electronics (H.K.) Ltd.
Rm. 803, World Trade Square, Tower II,
No. 4, Creation Rd. III,
123 Hoi Bun Rd., Kwun Tong,
Science-Based Industrial Park,
Kowloon, Hong Kong
Hsinchu, Taiwan
TEL: 852-27513100
TEL: 886-3-5770066
FAX: 852-27552064
FAX: 886-3-5792766
http://www.winbond.com.tw/
Voice & Fax-on-demand: 886-2-27197006
Winbond Electronics North America Corp.
Winbond Memory Lab.
Winbond Microelectronics Corp.
Winbond Systems Lab.
2727 N. First Street, San Jose,
CA 95134, U.S.A.
TEL: 408-9436666
FAX: 408-5441798
Taipei Office
11F, No. 115, Sec. 3, Min-Sheng East Rd.,
Taipei, Taiwan
TEL: 886-2-27190505
FAX: 886-2-27197502
Note: All data and specifications are subject to change without notice.
- 35 -
Publication Release Date: April 2001
Revision A1