PHILIPS PXAG39KBA

INTEGRATED CIRCUITS
XA-G39
XA 16-bit microcontroller family
32K FLASH/1K RAM, watchdog, 2 UARTs
Preliminary data
2002 Mar 13
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
• Boot ROM contains low level Flash programming routines for
GENERAL DESCRIPTION
The XA-G39 is a member of Philips’ 80C51 XA (eXtended
Architecture) family of high performance 16-bit single-chip
microcontrollers.
In-Application Programming and a default serial loader using the
UART
• 1024 bytes of on-chip data RAM
• Supports off-chip program and data addressing up to 1 megabyte
The XA-G39 contains 32 kbytes of Flash program memory, and
provides three general purpose timers/counters, a watchdog timer,
dual UARTs, and four general purpose I/O ports with programmable
output configurations.
(20 address lines)
• Three standard counter/timers with enhanced features (same as
XA-G3 T0, T1, and T2). All timers have a toggle output capability
A default serial loader program in the Boot ROM allows In-System
Programming (ISP) of the Flash memory without the need for a
loader in the Flash code. User programs may erase and reprogram
the Flash memory at will through the use of standard routines
contained in the Boot ROM (In-Application Programming).
• Watchdog timer
• Two enhanced UARTs with independent baud rates
• Seven software interrupts
• Four 8-bit I/O ports, with 4 programmable output configurations for
each pin
FEATURES
• 30 MHz operating frequency at 5 V
• Power saving operating modes: Idle and Power-Down.
• 32 kbytes of on-chip Flash program memory with In-System
Programming capability
• Three Flash blocks = two 8 kbyte blocks and one 16 kbyte block
• Provides Flash solution for XA-G37 (OTP) designs
• Single supply voltage In-System Programming (ISP) of the Flash
Wake-Up from power-down via an external interrupt is supported.
• 44-pin PLCC package
memory (VPP = VDD, or VPP = 12 V if desired)
BLOCK DIAGRAM
XA CPU Core
Program
Memory
Bus
SFR
bus
UART 0
32 KBYTES
FLASH
1024 BYTES
STATIC RAM
Data
Bus
UART 1
TIMER 0, 1
PORT 0
PORT 1
TIMER 2
PORT 2
WATCHDOG
TIMER
PORT 3
SU01594
2002 Mar 13
2
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
ORDERING INFORMATION
FLASH
TEMPERATURE RANGE (°C)
AND PACKAGE
FREQ.
(MHz)
DRAWING
NUMBER
PXAG39KBA
0 to +70
44-pin Plastic Leaded Chip Carrier
30
SOT187-2
LOGIC SYMBOL
VDD
VSS
XTAL1
XTAL2
RXD1
A3
A2
A1
A0/WRH
ADDRESS
BUS
PORT 1
T2EX
T2
TXD1
RST
EA/WAIT
PORT 0
RxD0
TxD0
INT0
INT1
T0
T1/BUSW
WRL
RD
PORT 3
ALTERNATE FUNCTIONS
ALE
ADDRESS AND DATA BUS
PORT 2
PSEN
SU01588
2002 Mar 13
3
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
PINNING INFORMATION
44-Pin PLCC Package
6
1
40
7
39
PLCC
17
29
18
Pin
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
2002 Mar 13
Function
VSS
P1.0/A0/WRH
P1.1/A1
P1.2/A2
P1.3/A3
P1.4/RxD1
P1.5/TxD1
P1.6/T2
P1.7/T2EX
RST
P3.0/RxD0
NC
P3.1/TxD0
P3.2/INT0
P3.3/INT1
P3.4/T0
P3.5/T1/BUSW
P3.6/WRL
P3.7/RD
XTAL2
XTAL1
VSS
28
Pin
23
24
25
26
27
28
29
30
31
32
33
34
35
36
37
38
39
40
41
42
43
44
Function
VDD
P2.0/A12D8
P2.1/A13D9
P2.2/A14D10
P2.3/A15D11
P2.4/A16D12
P2.5/A17D13
P2.6/A18D14
P2.7/A19D15
PSEN
ALE
NC
EA/VPP/WAIT
P0.7/A11D7
P0.6/A10D6
P0.5/A9D5
P0.4/A8D4
P0.3/A7D3
P0.2/A6D2
P0.1/A5D1
P0.0/A4D0
VDD
SU01035
4
XA-G39
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
PIN DESCRIPTION
MNEMONIC
PIN
NO.
TYPE
NAME AND FUNCTION
VSS
1, 22
I
Ground: 0 V reference.
VDD
23, 44
I
Power Supply: This is the power supply voltage for normal, idle, and power down operation.
P0.0 – P0.7
43–36
I/O
Port 0: Port 0 is an 8-bit I/O port with a user-configurable output type. Port 0 latches have 1s written to
them and are configured in the quasi-bidirectional mode during reset. The operation of port 0 pins as
inputs and outputs depends upon the port configuration selected. Each port pin is configured
independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for
details.
When the external program/data bus is used, Port 0 becomes the multiplexed low data/instruction byte and
address lines 4 through 11.
P1.0 – P1.7
P2.0 – P2.7
2–9
I/O
2
O
3
4
5
6
7
8
9
O
O
O
I
O
I/O
I
24–31
I/O
Port 1: Port 1 is an 8-bit I/O port with a user-configurable output type. Port 1 latches have 1s written to
them and are configured in the quasi-bidirectional mode during reset. The operation of port 1 pins as
inputs and outputs depends upon the port configuration selected. Each port pin is configured
independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for
details.
Port 1 also provides special functions as described below.
A0/WRH:
Address bit 0 of the external address bus when the external data bus is configured for
an 8 bit width. When the external data bus is configured for a 16 bit width, this pin
becomes the high byte write strobe.
A1:
Address bit 1 of the external address bus.
A2:
Address bit 2 of the external address bus.
A3:
Address bit 3 of the external address bus.
RxD1 (P1.4):
Receiver input for serial port 1.
TxD1 (P1.5):
Transmitter output for serial port 1.
T2 (P1.6):
Timer/counter 2 external count input/clockout.
T2EX (P1.7):
Timer/counter 2 reload/capture/direction control
Port 2: Port 2 is an 8-bit I/O port with a user-configurable output type. Port 2 latches have 1s written to
them and are configured in the quasi-bidirectional mode during reset. The operation of port 2 pins as
inputs and outputs depends upon the port configuration selected. Each port pin is configured
independently. Refer to the section on I/O port configuration and the DC Electrical Characteristics for
details.
When the external program/data bus is used in 16-bit mode, Port 2 becomes the multiplexed high
data/instruction byte and address lines 12 through 19. When the external program/data bus is used in 8-bit
mode, the number of address lines that appear on port 2 is user programmable.
P3.0 – P3.7
11,
13–19
I/O
11
13
14
15
16
17
I
O
I
I
I/O
I/O
18
19
O
O
RST
10
I
ALE
33
I/O
2002 Mar 13
Port 3: Port 3 is an 8-bit I/O port with a user configurable output type. Port 3 latches have 1s written to
them and are configured in the quasi-bidirectional mode during reset. the operation of port 3 pins as inputs
and outputs depends upon the port configuration selected. Each port pin is configured independently.
Refer to the section on I/O port configuration and the DC Electrical Characteristics for details.
Port 3 also provides various special functions as described below.
RxD0 (P3.0):
Receiver input for serial port 0.
TxD0 (P3.1):
Transmitter output for serial port 0.
INT0 (P3.2):
External interrupt 0 input.
INT1 (P3.3):
External interrupt 1 input.
T0 (P3.4):
Timer 0 external input, or timer 0 overflow output.
T1/BUSW (P3.5): Timer 1 external input, or timer 1 overflow output. The value on this pin is latched
as the external reset input is released and defines the default external data bus
width (BUSW). 0 = 8-bit bus and 1 = 16-bit bus.
WRL (P3.6):
External data memory low byte write strobe.
RD (P3.7):
External data memory read strobe.
Reset: A low on this pin resets the microcontroller, causing I/O ports and peripherals to take on their
default states, and the processor to begin execution at the address contained in the reset vector. Refer to
the section on Reset for details.
Address Latch Enable: A high output on the ALE pin signals external circuitry to latch the address portion
of the multiplexed address/data bus. A pulse on ALE occurs only when it is needed in order to process a
bus cycle.
5
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
MNEMONIC
PIN
NO.
TYPE
NAME AND FUNCTION
PSEN
32
O
Program Store Enable: The read strobe for external program memory. When the microcontroller
accesses external program memory, PSEN is driven low in order to enable memory devices. PSEN is only
active when external code accesses are performed.
EA/WAIT/
VPP
35
I
External Access/Wait/Programming Supply Voltage: The EA input determines whether the internal
program memory of the microcontroller is used for code execution. The value on the EA pin is latched as
the external reset input is released and applies during later execution. When latched as a 0, external
program memory is used exclusively, when latched as a 1, internal program memory will be used up to its
limit, and external program memory used above that point. After reset is released, this pin takes on the
function of bus Wait input. If Wait is asserted high during any external bus access, that cycle will be
extended until Wait is released. During EPROM programming, this pin is also the programming supply
voltage input.
XTAL1
21
I
Crystal 1: Input to the inverting amplifier used in the oscillator circuit and input to the internal clock
generator circuits.
XTAL2
20
O
Crystal 2: Output from the oscillator amplifier.
SPECIAL FUNCTION REGISTERS
NAME
DESCRIPTION
BIT FUNCTIONS AND ADDRESSES
SFR
ADDRESS
MSB
LSB
RESET
VALUE
AUXR
Auxiliary function register
44C
ENBOOT
FMIDLE
PWR_VLD
—
—
—
—
—
BCR
Bus configuration register
46A
—
—
—
WAITD
BUSD
BC2
BC1
BC0
BTRH
Bus timing register high byte
469
DW1
DW0
DWA1
DWA0
DR1
DR0
DRA1
DRA0
FF
BTRL
Bus timing register low byte
468
WM1
WM0
ALEW
—
CR1
CR0
CRA1
CRA0
EF
CS
DS
ES
Code segment
Data segment
Extra segment
443
441
442
00
00
00
33F
IEH*
Interrupt enable high byte
427
Note 1
33E
33D
33C
33B
33A
339
338
—
—
—
—
ETI1
ERI1
ETI0
ERI0
337
336
335
334
333
332
331
330
—
—
ET2
ET1
EX1
ET0
EX0
00
IEL*
Interrupt enable low byte
426
EA
IPA0
Interrupt priority 0
4A0
—
PT0
—
PX0
00
IPA1
Interrupt priority 1
4A1
—
PT1
—
PX1
00
IPA2
Interrupt priority 2
4A2
—
—
—
PT2
00
IPA4
Interrupt priority 4
4A4
—
PTI0
—
PRI0
00
IPA5
Interrupt priority 5
4A5
—
PTI1
—
PRI1
00
P0*
P1*
P2*
P3*
Port 0
Port 1
Port 2
Port 3
2002 Mar 13
430
431
432
433
387
386
385
384
383
382
381
380
AD7
AD6
AD5
AD4
AD3
AD2
AD1
AD0
38F
38E
38D
38C
38B
38A
389
388
T2EX
T2
TxD1
RxD1
A3
A2
A1
WRH
397
396
395
394
393
392
391
390
P2.7
P2.6
P2.5
P2.4
P2.3
P2.2
P2.1
P2.0
39F
39E
39D
39C
39B
39A
399
398
RD
WR
T1
T0
INT1
INT0
TxD0
RxD0
6
00
FF
FF
FF
FF
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
DESCRIPTION
NAME
SFR
ADDRESS
XA-G39
BIT FUNCTIONS AND ADDRESSES
MSB
LSB
RESET
VALUE
P0CFGA
Port 0 configuration A
470
Note 5
P1CFGA
Port 1 configuration A
471
Note 5
P2CFGA
Port 2 configuration A
472
Note 5
P3CFGA
Port 3 configuration A
473
Note 5
P0CFGB
Port 0 configuration B
4F0
Note 5
P1CFGB
Port 1 configuration B
4F1
Note 5
P2CFGB
Port 2 configuration B
4F2
Note 5
P3CFGB
Port 3 configuration B
4F3
Note 5
PCON*
Power control register
404
PSWH*
Program status word
(high byte)
401
PSWL*
Program status word (low byte)
400
227
226
225
224
223
222
221
220
—
—
—
—
—
—
PD
IDL
20F
20E
20D
20C
20B
20A
209
208
SM
TM
RS1
RS0
IM3
IM2
IM1
IM0
207
206
205
204
203
202
201
200
C
AC
—
—
—
V
N
Z
217
216
215
214
213
212
211
210
C
AC
F0
RS1
RS0
V
F1
P
00
Note 2
Note 2
PSW51*
80C51 compatible PSW
402
RTH0
Timer 0 extended reload,
high byte
Timer 1 extended reload,
high byte
Timer 0 extended reload,
low byte
Timer 1 extended reload,
low byte
455
00
457
00
454
00
456
00
RTH1
RTL0
RTL1
S0CON*
Serial port 0 control register
420
307
306
305
304
303
302
301
300
SM0_0
SM1_0
SM2_0
REN_0
TB8_0
RB8_0
TI_0
RI_0
30F
30E
30D
30C
30B
30A
309
308
—
—
—
—
FE0
BR0
OE0
STINT0
Note 3
00
S0STAT*
Serial port 0 extended status
421
S0BUF
S0ADDR
S0ADEN
Serial port 0 buffer register
Serial port 0 address register
Serial port 0 address enable
register
460
461
462
S1CON*
Serial port 1 control register
424
S1STAT*
Serial port 1 extended status
425
S1BUF
S1ADDR
S1ADEN
Serial port 1 buffer register
Serial port 1 address register
Serial port 1 address enable
register
464
465
466
SCR
System configuration register
440
—
21F
21E
21D
21C
21B
21A
219
218
SSEL*
Segment selection register
403
ESWEN
R6SEG
R5SEG
R4SEG
R3SEG
R2SEG
R1SEG
R0SEG
00
SWE
Software Interrupt Enable
47A
—
SWE7
SWE6
SWE5
SWE4
SWE3
SWE2
SWE1
00
2002 Mar 13
00
x
00
00
327
326
325
324
323
322
321
320
SM0_1
SM1_1
SM2_1
REN_1
TB8_1
RB8_1
TI_1
RI_1
32F
32E
32D
32C
32B
32A
329
328
—
—
—
—
FE1
BR1
OE1
STINT1
00
00
x
00
00
—
7
—
—
PT1
PT0
CM
PZ
00
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
DESCRIPTION
NAME
SFR
ADDRESS
XA-G39
BIT FUNCTIONS AND ADDRESSES
MSB
LSB
357
356
355
354
353
352
351
350
—
SWR7
SWR6
SWR5
SWR4
SWR3
SWR2
SWR1
RESET
VALUE
SWR*
Software Interrupt Request
42A
T2CON*
Timer 2 control register
418
T2MOD*
Timer 2 mode control
419
TH2
TL2
T2CAPH
Timer 2 high byte
Timer 2 low byte
Timer 2 capture register,
high byte
Timer 2 capture register,
low byte
459
458
45B
00
00
00
45A
00
T2CAPL
2C7
2C6
2C5
2C4
2C3
2C2
2C1
2C0
TF2
EXF2
RCLK0
TCLK0
EXEN2
TR2
C/T2
CP/RL2
2CF
2CE
2CD
2CC
2CB
2CA
2C9
2C8
—
—
RCLK1
TCLK1
—
—
T2OE
DCEN
287
286
285
284
283
282
281
280
TF1
TR1
TF0
TR0
IE1
IT1
IE0
IT0
TCON*
Timer 0 and 1 control register
410
TH0
TH1
TL0
TL1
Timer 0 high byte
Timer 1 high byte
Timer 0 low byte
Timer 1 low byte
451
453
450
452
TMOD
Timer 0 and 1 mode control
45C
TSTAT*
Timer 0 and 1 extended status
411
2FF
WDCON*
Watchdog control register
41F
PRE2
WDL
Watchdog timer reload
Watchdog feed 1
Watchdog feed 2
45F
45D
45E
WFEED1
WFEED2
00
00
00
00
00
00
00
00
GATE
C/T
M1
M0
GATE
C/T
M1
28F
28E
28D
28C
—
—
—
—
2FE
2FD
2FC
2FB
PRE1
PRE0
—
—
M0
28B
28A
289
288
—
T1OE
—
T0OE
2FA
2F9
2F8
WDRUN
WDTOF
—
00
00
Note 6
00
x
x
NOTES:
* SFRs are bit addressable.
1. At reset, the BCR register is loaded with the binary value 0000 0a11, where “a” is the value on the BUSW pin. This defaults the address bus
size to 20 bits since the XA-G39 has only 20 address lines.
2. SFR is loaded from the reset vector.
3. All bits except F1, F0, and P are loaded from the reset vector. Those bits are all 0.
4. Unimplemented bits in SFRs are X (unknown) at all times. Ones should not be written to these bits since they may be used for other
purposes in future XA derivatives. The reset value shown for these bits is 0.
5. Port configurations default to quasi-bidirectional when the XA begins execution from internal code memory after reset, based on the
condition found on the EA pin. Thus all PnCFGA registers will contain FF and PnCFGB registers will contain 00. When the XA begins
execution using external code memory, the default configuration for pins that are associated with the external bus will be push-pull. The
PnCFGA and PnCFGB register contents will reflect this difference.
6. The WDCON reset value is E6 for a Watchdog reset, E4 for all other reset causes.
7. The XA-G39 implements an 8-bit SFR bus, as stated in Chapter 8 of the XA User Guide. All SFR accesses must be 8-bit operations. Attempts
to write 16 bits to an SFR will actually write only the lower 8 bits. Sixteen bit SFR reads will return undefined data in the upper byte.
8. The AUXR reset value is typically 00h. If the Boot Loader is activated at reset because the Flash status byte is non-zero or because the Boot
Vector has been forced (by PSEN = 0, ALE = 1, EA = 1 at reset), the AUXR reset value will be 1x00 0000b. Bit 6 will be a 1 if the on-chip
VPP generator is running and ready, otherwise it will be a 0.
2002 Mar 13
8
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
FFFFFh
UP TO 1 MBYTE
TOTAL CODE
MEMORY
FFFFh
2 KBYTES BOOT ROM
F800h
8000h
7FFFh
32 KBYTES
ON-CHIP
CODE MEMORY
0000h
Note: The Boot ROM is enabled via the ENBOOT bit in register AUXR.
SU01589
Figure 1. XA-G39 Program Memory Map
Data Segment 0
Other Data Segments
FFFFFh
FFFFFh
DATA MEMORY
(INDIRECTLY ADDRESSED,
OFF-CHIP)
1 KBYTE
ON-CHIP DATA
MEMORY
(RAM)
DATA MEMORY
(INDIRECTLY ADDRESSED,
OFF-CHIP)
0400H
0400H
03FFh
03FFh
DATA MEMORY
(DIRECTLY AND INDIRECTLY
ADDRESSABLE, OFF-CHIP)
DATA MEMORY
(DIRECTLY AND INDIRECTLY
ADDRESSABLE, ON CHIP)
0040h
BIT-ADDRESSABLE
DATA AREA
DATA MEMORY
(DIRECTLY AND INDIRECTLY
ADDRESSABLE, ON CHIP)
DIRECTLY ADDRESSED DATA
(1k PER SEGMENT)
0040h
003Fh
003Fh
0020h
0020h
001Fh
001Fh
0000h
0000h
BIT-ADDRESSABLE
DATA AREA
DATA MEMORY
(DIRECTLY AND INDIRECTLY
ADDRESSABLE, OFF-CHIP)
SU01590
Figure 2. XA-G39 Data Memory Map
2002 Mar 13
9
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
FLASH EPROM MEMORY
CAPABILITIES OF THE PHILIPS XA-G39
FLASH-BASED MICROCONTROLLERS
GENERAL DESCRIPTION
Flash organization
The XA-G39 Flash memory augments EPROM functionality with
in-circuit electrical erasure and programming. The Flash can be read
and written as bytes. The Chip Erase operation will erase the entire
program memory. The Block Erase function can erase any single
Flash block. In-circuit programming and standard parallel
programming are both available. On-chip erase and write timing
generation contribute to a user friendly programming interface.
The XA-G39 contains 32 kbytes of Flash program memory. This
memory is organized as 3 separate blocks. The first two blocks are
8 kbytes in size, filling the program memory space from address 0
through 3FFF hex. The final block is 16 kbytes in size and occupies
addresses 4000 through 7FFF hex.
Figure 3 depicts the Flash memory configuration.
The XA-G39 Flash reliably stores memory contents even after
10,000 erase and program cycles. The cell is designed to optimize
the erase and programming mechanisms. In addition, the
combination of advanced tunnel oxide processing and low internal
electric fields for erase and programming operations produces
reliable cycling. For In-System Programming, the XA-G39 can use a
single +5 V power supply. Faster In-System Programming may be
obtained, if required, through the use of a +12 V VPP supply.
Parallel programming (using separate programming hardware) uses
a +12 V VPP supply.
Flash Programming and Erasure
The XA-G39 Flash microcontroller supports a number of
programming possibilities for the on-chip Flash memory. The Flash
memory may be programmed in a parallel fashion on standard
programming equipment in a manner similar to an EPROM
microcontroller. The XA-G39 microcontroller is able to program its
own Flash memory while the application code is running. Also, a
default loader built into a Boot ROM allows programming blank
devices serially through the UART.
Using any of these types of programming, any of the individual blocks
may be erased separately, or the entire chip may be erased.
Programming of the Flash memory is accomplished one byte at a time.
FEATURES
• Flash EPROM internal program memory with Single Voltage
Boot ROM
Programming and Block Erase capability.
When the microcontroller programs its own Flash memory, all of the
low level details are handled by code that is permanently contained
in a 2 kbyte “Boot ROM” that is separate from the Flash memory. A
user program simply calls the entry point with the appropriate
parameters to accomplish the desired operation. Boot ROM
operations include things like: erase block, program byte, verify
byte, program security lock bit, etc. The Boot ROM overlays the
program memory space from F800 to FFFF hex, when it is enabled
by setting the ENBOOT bit at AUXR.7. The Boot ROM may be turned
off so that the underlying address space becomes available.
• Internal 2 kbyte fixed boot ROM, containing low-level
programming routines and a default loader. The Boot ROM can
be turned on and off via ENBOOT in the AUXR register.
• The boot vector allows a user provided Flash loader code to
reside anywhere in the Flash memory space. This configuration
provides flexibility to the user.
• The default loader in Boot ROM allows programming via the serial
port without the need for a user-provided loader.
• Up to 1 Mbyte external program memory if the internal program
ENBOOT and PWR_VLD
Setting the ENBOOT bit in the AUXR register enables the Boot
ROM and activates the on-chip VPP generator if VPP is connected to
VDD rather than 12 V externally. The PWR_VLD flag indicates that
VPP is available for programming and erase operations. This flag
should be checked prior to calling the Boot ROM for programming
and erase services. When ENBOOT is set, it typically takes
5 microseconds for the internal programming voltage to be ready.
memory is disabled (EA = 0).
• Programming and erase voltage: VPP = VDD (5 V power supply),
or 12 V ±5% for In System Programming. Using 12 V VPP for ISP
improves programming and erase time.
• Read/Programming/Erase in ISP:
– Byte-wise read (60 ns access time at 4.5 V).
The ENBOOT bit will automatically be set if the status byte is
non-zero during reset, or when PSEN is low, ALE is high, and EA is
high at the falling edge of reset. Otherwise, ENBOOT will be cleared
during reset.
– Byte Programming (0.5–1 minute for 32 K flash, depending on
clock frequency).
• In-circuit programming via user selected method, typically RS232
or parallel I/O port interface.
• Programmable security for the code in the Flash.
• 10,000 minimum erase/program cycles each byte over operating
When programming functions are not needed, ENBOOT may be
cleared. This enables access to the 2 kbytes of Flash code memory
that is overlaid by the Boot ROM, allowing a full 32 kbytes of Flash
code memory.
temperature range.
• 10 year minimum data retention.
2002 Mar 13
XA-G39
10
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
7FFF
BLOCK 2
16 KBYTES
PROGRAM
ADDRESS
4000
BLOCK 1
8 KBYTES
2000
BLOCK 0
8 KBYTES
0000
SU01591
Figure 3. Flash Memory Configuration
Program Counter (BPC) and the Boot PSW (BPSW). The factory
default settings are 8000h for the BPSW and F800h for the BPC,
which corresponds to the address F900h for the factory masked-ROM
ISP boot loader. The Status Byte is automatically set to a non-zero
value when a programming error occurs. A custom boot loader can
be written with the Boot Vector set to the custom boot loader.
FMIDLE
The FMIDLE bit in the AUXR register allows saving additional power
by turning off the Flash memory when the CPU is in the Idle mode.
This must be done just prior to initiating the Idle mode, as shown
below.
OR
AUXR,#$40
OR
.
PCON,#$01
.
; Set Flash memory
to idle mode.
; Turn on Idle mode.
; Execution resumes
here when Idle
mode terminates.
NOTE: When erasing the Status Byte or Boot Vector, these
bytes are erased at the same time. It is necessary to reprogram
the Boot Vector after erasing and updating the Status Byte.
Hardware Activation of the Boot Vector
Program execution at the Boot Vector may also be forced from
outside of the microcontroller by setting the correct state on a few
pins. While Reset is asserted, the PSEN pin must be pulled low, the
ALE pin allowed to float high (need not be pulled up externally), and
the EA pin driven to a logic high (or up to VPP). Then reset may be
released. This is the same effect as having a non-zero status byte.
This allows building an application that will normally execute the end
user’s code but can be manually forced into ISP operation. The Boot
ROM is enabled when use of the Boot Vector is forced as described
above, so the branch may go to the default loader. Conversely, user
code in the program memory space from F800h to FFFFh may not
be executed when the Boot Vector is used.
When the Flash memory is put into the Idle mode by setting FMIDLE,
restarting the CPU upon exiting Idle mode takes slightly longer,
about 3 microseconds. However, the standby current consumed by
the Flash memory is reduced from about 8mA to about 1mA.
Default Loader
A default loader that accepts programming commands in a
predetermined format is contained permanently in the Boot ROM. A
factory fresh device will enter this loader automatically if it is
powered up without first being programmed by the user. Loader
commands include functions such as erase block; program Flash
memory; read Flash memory; and blank check.
If the factory default setting for the BPC (F800h) is changed, it will
no longer point to the ISP masked-ROM boot loader code. If this
happens, the only possible way to change the contents of the Boot
Vector is through the parallel programming method, provided that
the end user application does not contain a customized loader that
provides for erasing and reprogramming of the Boot Vector and
Status Byte.
Boot Vector
The XA-G39 contains two special FLASH registers: the BOOT
VECTOR and the STATUS BYTE.
The “Boot Vector” allows forcing the execution of a user supplied
Flash loader upon reset, under two specific sets of conditions. At the
falling edge of reset, the XA-G39 examines the contents of the
Status Byte. If the Status Byte is set to zero, power-up execution
starts at location 0000H, which is the normal start address of the
user’s application code.
After programming the FLASH, the status byte should be erased to
zero in order to allow execution of the user’s application code
beginning at address 0000H.
When the Status Byte is set to a value other than zero, the Boot
Vector is used as the reset vector (4 bytes), including the Boot
2002 Mar 13
11
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
VCC
VPP
VDD SUPPLY OR +12V ±5%
FOR USE WITH WINISP OR FLASHMAGIC
VDD
5V ±5%
TxD
TxD
2
RxD
RxD
3
RST
XTAL2
VSS
RS-232
TRANSCEIVER
MC145406, MAX232,
OR EQUIVALENT
5
FEMALE
DB-9
XTAL1
VSS
SU01593
Figure 4. In-System Programming with a Minimum of Pins
There is also an application note available that deals with In-System
Programming (AN716). At www.philipsmcu.com, search for “ISP”,
then select AN716 from the search results.
In-System Programming (ISP)
In-System Programming (ISP) is performed without removing the
microcontroller from the system. The In-System Programming (ISP)
facility consists of a series of internal hardware resources coupled
with internal firmware to facilitate remote programming of the
XA-G39 through the serial port. This firmware is provided by Philips
and embedded within each XA-G39 device.
Using In-System Programming (ISP)
ISP mode is entered by holding PSEN low, asserting, un-asserting
RESET, then releasing PSEN. When ISP mode is entered, the
default loader first disables the watchdog timer to prevent a
watchdog reset from occurring during programming.
The Philips In-System Programming (ISP) facility has made in-circuit
programming in an embedded application possible with a minimum
of additional expense in components and circuit board area.
The ISP feature allows for a wide range of baud rates to be used in
the application, independent of the oscillator frequency. It is also
adaptable to a wide range of oscillator frequencies. This is
accomplished by measuring the bit-time of a single bit in a received
character. This information is then used to program the baud rate in
terms of timer counts based on the oscillator frequency. The ISP
feature requires that an initial character (a lowercase f) be sent to
the XA-G39 to establish the baud rate. The ISP firmware provides
auto-echo of received characters.
The ISP function uses five pins: TxD, RxD, VSS, VDD, and VPP (see
Figure 4). Only a small connector needs to be available to interface
your application to an external circuit in order to use this feature.
The VPP supply should be adequately decoupled and VPP not
allowed to exceed datasheet limits.
VCC
VPP
OSC FREQ
IDD
5.0 V
5.0 V
22 MHz
75 mA typical
5.0 V
5.0 V
30 MHz
90 mA typical
Once baud rate initialization has been performed, the ISP firmware
will only accept specific Intel Hex-type records. Intel Hex records
consist of ASCII characters used to represent hexadecimal values
and are summarized below:
ISP increases IDD by less than 1mA.
:NNAAAARRDD..DDCC<crlf>
Free ISP software is available on the Philips web site: “WinISP”
In the Intel Hex record, the “NN” represents the number of data
bytes in the record. The XA-G39 will accept up to 16 (10H) data
bytes. The “AAAA” string represents the address of the first byte in
the record. If there are zero bytes in the record, this field is often set
to 0000. The “RR” string indicates the record type. A record type of
“00” is a data record. A record type of “01” indicates the end-of-file
mark. In this application, additional record types will be added to
indicate either commands or data for the ISP facility. The maximum
number of data bytes in a record is limited to 16 (decimal). ISP
commands are summarized in Table 1.
1. Direct your browser to the following page:
http://www.semiconductors.com/mcu/download/80C51/flash/
2. Download “WinISP.exe”
3. Execute WinISP.exe to install the software
Free ISP software is also available from the Embedded Systems
Academy: “FlashMagic”
1. Direct your browser to the following page:
http://www.esacademy.com/software/flashmagic/
As a record is received by the XA-G39, the information in the record
is stored internally and a checksum calculation is performed. The
2. Download Flashmagic
3. Execute “flashmagic.exe” to install the software
2002 Mar 13
12
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
RS-232, serially using some other method, or even parallel over a
user defined I/O port. The user has the freedom to choose a method
that does not interfere with the application circuit. As an added
feature, the application program may also use the Flash memory as
a long term data storage, saving configuration information, sensor
readings, or any other desired data.
operation indicated by the record type is not performed until the
entire record has been received. Should an error occur in the
checksum, the XA-G39 will send an “X” out the serial port indicating
a checksum error. If the checksum calculation is found to match the
checksum in the record, then the command will be executed. In
most cases, successful reception of the record will be indicated by
transmitting a “.” character out the serial port (displaying the
contents of the internal program memory is an exception).
The actual loader code would typically be programmed by the user
into the microcontroller in a parallel fashion or via the default loader
during their manufacturing process. The entire initial Flash contents
may be programmed at that time, or the rest of the application may
be programmed into the Flash memory at a later time, possibly
using the loader code to do the programming.
In the case of a Data Record (record type 00), an additional check is
made. A “.” character will NOT be sent unless the record checksum
matched the calculated checksum and all of the bytes in the record
were successfully programmed. For a data record, an “X” indicates
that the checksum failed to match, and an “R” character indicates
that one of the bytes did not properly program.
This application controlled programming capability allows for the
possibility of changing the application code in the field. If the
application circuit is embedded in a PC, or has a way to establish a
telephone data link to a user’s or manufacturer’s computer, new
code could be downloaded from diskette or a manufacturer’s
support system. There is even the possibility of conducting very
specialized remote testing of a failing circuit board by the
manufacturer by remotely programming a series of detailed test
programs into the application board and checking the results.
The ISP facility was designed so that specific crystal frequencies
were not required in order to generate baud rates or time the
programming pulses.
User Supplied Loader
A user program can simply decide at any time, for any reason, to
begin Flash programming operations. All it has to do in advance is to
instruct external circuitry to apply +5 V or +12 V to the VPP pin, and
make certain that the Boot ROM is enabled. User code may contain
a loader designed to replace the application code contained in the
Flash memory by loading new code through any communication
medium available in the application. This is completely flexible and
defined by the designer of the system. It could be done serially using
2002 Mar 13
XA-G39
Any user supplied loader should take the watchdog timer into
account. Typically, the watchdog timer would be disabled upon entry
to the loader if it might be running, in order to prevent a watchdog
reset from occurring during programming.
13
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
Table 1. Intel-Hex Records Used by In-System Programming
RECORD TYPE
00 or 80
COMMAND/DATA FUNCTION
Data Record
:nnaaaa00dd....ddcc
Where:
Nn
Aaaa
dd....dd
cc
=
=
=
=
number of bytes (hex) in record
memory address of first byte in record
data bytes
checksum
Example:
:10008000AF5F67F0602703E0322CFA92007780C3FD
01 or 81
End of File (EOF), no operation
:xxxxxx01cc
Where:
xxxxxx
cc
= required field, but value is a “don’t care”
= checksum
Example:
:00000001FF
83
Miscellaneous Write Functions
:nnxxxx83ffssddcc
Where:
nn
xxxx
83
ff
ss
dd
cc
=
=
=
=
=
=
=
number of bytes (hex) in record
required field, but value is a “don’t care”
Write Function
subfunction code
selection code
data input (as needed)
checksum
Subfunction Code = 01 (Erase Blocks)
ff = 01
ss = block number in bits 7:5, Bits 4:0 = zeros
block 0 : ss = 00h
block 1 : ss = 20h
block 2 : ss = 40h
Example:
:0200008301203C erase block 1
Subfunction Code = 04 (Erase Boot Vector and Status Byte)
ff = 04
ss = don’t care
dd = don’t care
Example:
:010000830478 erase boot vector and status byte
Subfunction Code = 05 (Program Security Bits)
ff = 05
ss = 00 program security bit 1 (inhibit writing to FLASH)
01 program security bit 2 (inhibit FLASH verify)
02 program security bit 3 (disable external memory)
Example:
:02000083050175 program security bit 2
Subfunction Code = 06 (Program Status Byte or Boot Vector)
ff = 06
ss = 00 program status byte
01 program boot vector
NOTE: Only two bits of these Special Cells may be programmed at one time.
Example:
:020000830601FC78
2002 Mar 13
program boot vector to FC00h
14
XA-G39
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
RECORD TYPE
84
XA-G39
COMMAND/DATA FUNCTION
Display Device Data or Blank Check – Record type 84 causes the contents of the entire FLASH array to be sent out
the serial port in a formatted display. This display consists of an address and the contents of 16 bytes starting with that
address. No display of the device contents will occur if security bit 2 has been programmed. The dumping of the device
data to the serial port is terminated by the reception of any character.
General Format of Function 84
:05xxxx84sssseeeeffcc
Where:
05
xxxx
84
ssss
eeee
ff
cc
=
=
=
=
=
=
number of bytes (hex) in record
required field, but value is a “don’t care”
“Display Device Data or Blank Check” function code
starting address
ending address
subfunction
00 = display data
01 = blank check
= checksum
Example:
:0500008440004FFF00E9
85
display 4000–4FFF
Miscellaneous Read Functions
General Format of Function 85
:02xxxx85ffsscc
Where:
02
xxxx
85
ffss
cc
=
=
=
=
number of bytes (hex) in record
required field, but value is a “don’t care”
“Miscellaneous Read” function code
subfunction and selection code
0000 = read signature byte – manufacturer id (15H)
0001 = read signature byte – device id # 1
(EAH)
0002 = read signature byte – device id # 2
(XA–G39 = 65H))
0700 = read security bits (returned value bits 3:1 = sb3,sb2,sb1)
0701 = read status byte
0702 = read boot vector
= checksum
Example:
:02000085000178
2002 Mar 13
read signature byte – device id # 1
15
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
common interface, PGM_MTP. The programming functions are
selected by setting up the microcontroller’s registers before making
a call to PGM_MTP at FFF0H. Results are returned in the registers.
The IAP calls are shown in Table 2.
In-Application Programming Method
Several In-Application Programming (IAP) calls are available for use
by an application program to permit selective erasing and
programming of FLASH sectors. All calls are made through a
Table 2. IAP calls
IAP CALL
PARAMETER
PROGRAM DATA BYTE
Input Parameters:
R0H = 02h or 92h
R6 = address of byte to program
R4L = byte to program
Return Parameter
R4L = 00 if pass, non-zero if fail
ERASE BLOCK
Input Parameters:
R0H = 01h or 93h
R6H = block number in bits 7:5, bits 4:0 = ’0’
block 0 : R6H = 00h
block 1 : R6H = 20h
block 2 : R6H = 40h
R6L = 00h
Return Parameter
R4L = 00 if pass, non-zero if fail
ERASE BPC and
STATUS BYTE
Input Parameters:
R0H = 04h
Return Parameter
R4L = 00 if pass, non-zero if fail
PROGRAM SECURITY BIT
Input Parameters:
R0H = 05h
R6H = 00h
R6L = 00h – security bit # 1 (inhibit writing to FLASH)
01h – security bit # 2 (inhibit FLASH verify)
02h – security bit # 3 (disable external memory)
Return Parameter
none
PROGRAM STATUS BYTE
Input Parameters:
R0H = 06h
R6H = 00h
R6L = 00h – program status byte
R4L = status byte
Return Parameter
R4L = 00 if pass, non-zero if fail
NOTE: Only two bits of this Special Cell may be programmed at one time.
PROGRAM BPC high byte
Input Parameters:
R0H = 06h
R6H = 00h
R6L = 01h – program BPC
R4L = BPC[15:8] (BPC[7:0] unchanged)
Return Parameter
R4L = 00 if pass, non-zero if fail
NOTE: Only two bits of this Special Cell may be programmed at one time.
READ DEVICE DATA
Input Parameters:
R0H = 03h
R6 = address of byte to read
Return Parameter
R4L = value of byte read
READ MANUFACTURER ID
Input Parameters:
R0H = 00h
R6H = 00h
R6L = 00h (manufacturer ID)
Return Parameter
R4L = value of byte read
2002 Mar 13
16
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
IAP CALL
XA-G39
PARAMETER
READ DEVICE ID # 1
Input Parameters:
R0H = 00h
R6H = 00h
R6L = 01h (device ID # 1)
Return Parameter
R4L = value of byte read
READ DEVICE ID # 2
Input Parameters:
R0H = 00h
R6H = 00h
R6L = 02h (device ID # 2)
Return Parameter
R4L = value of byte read
READ SECURITY BITS
Input Parameters:
R0H = 07h
R6H = 00h
R6L = 00h (security bits)
Return Parameter
R4L = value of byte read R4L[3:1] = sb3, sb2, sb1
READ STATUS BYTE
Input Parameters:
R0H = 07h
R6H = 00h
R6L = 01h (status byte)
Return Parameter
R4L = value of BPC[15:8]
READ BPC
Input Parameters:
R0H = 07h
R6H = 00h
R6L = 02h (boot vector)
Return Parameter
R4L = value of byte read (high byte of Boot PC)
PROGRAM ALL ZERO
Input Parameters:
R0H = 90h
R6H = block number in bits 7:5, bits 4:0 = ‘0’
block 0 : r6h = 00h
block 1 : r6h = 20h
block 2 : r6h = 40h
R6L = 00h
Return Parameters:
R4L = 00 if pass, non–zero if fail
ERASE CHIP
Input Parameters:
R0H = 91h
R4L = 55h
(after chip erase, return to caller)
= AAh
(after chip erase, reset chip)
= others: error
Return Parameters:
R4L = 00 if pass, non–zero if fail
PROGRAM SPECIAL CELL
Input Parameters:
R0H = 94h
R6 = special cell address
0000h: program BPSW[7:0]
0001h: program BPSW[15:8]
0002h: program BPC[7:0]
0003h: program BPC[15:8]
0004h: program status byte
000Ah: program security bit #1
000Ch: program security bit #2
000Eh: program security bit #3
R4L = byte value to program
Return Parameters:
R4L = 00 if pass, non–zero if fail
NOTE: Only two bits of these Special Cells may be programmed at one time.
2002 Mar 13
17
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
IAP CALL
XA-G39
PARAMETER
ERASE SPECIAL CELL
Input Parameters:
R0H = 95h
R6 = special cell address
0000h: erase BPSW[7:0]
0001h: erase BPSW[15:8]
0002h: erase BPC[7:0]
0003h: erase BPC[15:8]
0004h: erase status byte
Return Parameters:
R4L = 00 if pass, non–zero if fail
READ SPECIAL CELL
Input Parameters:
R0H = 96h
R6 = special cell address
0000h: read BPSW[7:0]
0001h: read BPSW[15:8]
0002h: read BPC[7:0]
0003h: read BPC[15:8]
0004h: read status byte
0006h: read manufacturer
0007h: read device ID #1
0008h: read device ID #2
000Ah: read security bit
000Ch: read security bit
000Eh: read security bit
Return Parameters:
R4L = value of byte read
ID
#1
#2
#3
Security
The security feature protects against software piracy and prevents the contents of the Flash from being read. The Security Lock bits are located
in Flash. The XA-G39 has 3 programmable security lock bits that will provide different levels of protection for the on-chip code and data (see
Table 3).
Table 3.
SECURITY LOCK BITS1
PROTECTION DESCRIPTION
Level
SB1
SB2
SB3
1
0
0
0
No program security features enabled.
2
1
0
0
Same as level 1, plus block erase is disabled. Erase or programming of the status byte or
boot vector is disabled.
3
1
1
0
Same as level 2, plus program verification is disabled
4
1
1
1
Same as level 3, plus external execution is disabled.
NOTE:
1. Any other combination of the Lock bits is not defined.
2. Security bits are independent of each other. Full-chip erase may be performed regardless of the states of the security bits.
3. Setting LB doesn’t prevent programming of unprogrammed bits.
2002 Mar 13
18
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
generation, Timer 2 capture. Note that this single rate setting applies
to all of the timers.
XA-G39 TIMER/COUNTERS
The XA has two standard 16-bit enhanced Timer/Counters: Timer 0
and Timer 1. Additionally, it has a third 16-bit Up/Down
timer/counter, T2. A central timing generator in the XA core provides
the time-base for all XA Timers and Counters. The timer/event
counters can perform the following functions:
– Measure time intervals and pulse duration
– Count external events
– Generate interrupt requests
– Generate PWM or timed output waveforms
When timers T0, T1, or T2 are used in the counter mode, the
register will increment whenever a falling edge (high to low
transition) is detected on the external input pin corresponding to the
timer clock. These inputs are sampled once every 2 oscillator
cycles, so it can take as many as 4 oscillator cycles to detect a
transition. Thus the maximum count rate that can be supported is
Osc/4. The duty cycle of the timer clock inputs is not important, but
any high or low state on the timer clock input pins must be present
for 2 oscillator cycles before it is guaranteed to be “seen” by the
timer logic.
All of the timer/counters (Timer 0, Timer 1 and Timer 2) can be
independently programmed to operate either as timers or event
counters via the C/T bit in the TnCON register. All timers count up
unless otherwise stated. These timers may be dynamically read
during program execution.
Timer 0 and Timer 1
The “Timer” or “Counter” function is selected by control bits C/T in
the special function register TMOD. These two Timer/Counters have
four operating modes, which are selected by bit-pairs (M1, M0) in
the TMOD register. Timer modes 1, 2, and 3 in XA are kept identical
to the 80C51 timer modes for code compatibility. Only the mode 0 is
replaced in the XA by a more powerful 16-bit auto-reload mode. This
will give the XA timers a much larger range when used as time
bases.
The base clock rate of all of the timers is user programmable. This
applies to timers T0, T1, and T2 when running in timer mode (as
opposed to counter mode), and the watchdog timer. The clock
driving the timers is called TCLK and is determined by the setting of
two bits (PT1, PT0) in the System Configuration Register (SCR).
The frequency of TCLK may be selected to be the oscillator input
divided by 4 (Osc/4), the oscillator input divided by 16 (Osc/16), or
the oscillator input divided by 64 (Osc/64). This gives a range of
possibilities for the XA timer functions, including baud rate
SCR
Address:440
Not Bit Addressable
Reset Value: 00H
PT1
PT0
0
0
1
1
CM
0
1
0
1
PZ
XA-G39
The recommended M1, M0 settings for the different modes are
shown in Figure 6.
MSB
—
LSB
—
—
—
PT1
PT0
CM
PZ
OPERATING
Prescaler selection.
Osc/4
Osc/16
Osc/64
Reserved
Compatibility Mode allows the XA to execute most translated 80C51 code on the XA. The
XA register file must copy the 80C51 mapping to data memory and mimic the 80C51 indirect
addressing scheme.
Page Zero mode forces all program and data addresses to 16-bits only. This saves stack space
and speeds up execution but limits memory access to 64k.
SU00589
Figure 5. System Configuration Register (SCR)
TMOD
Address:45C
Not Bit Addressable
Reset Value: 00H
MSB
GATE
LSB
C/T
M1
M0
GATE
TIMER 1
GATE
C/T
M1
0
0
1
1
M0
0
1
0
1
C/T
M1
TIMER 0
Gating control when set. Timer/Counter “n” is enabled only while “INTn” pin is high and
“TRn” control bit is set. When cleared Timer “n” is enabled whenever “TRn” control bit is set.
Timer or Counter Selector cleared for Timer operation (input from internal system clock.)
Set for Counter operation (input from “Tn” input pin).
OPERATING
16-bit auto-reload timer/counter
16-bit non-auto-reload timer/counter
8-bit auto-reload timer/counter
Dual 8-bit timer mode (timer 0 only)
Figure 6. Timer/Counter Mode Control (TMOD) Register
2002 Mar 13
M0
19
SU00605
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
reloads TLn with the contents of RTLn, which is preset by software.
The reload leaves THn unchanged.
New Enhanced Mode 0
For timers T0 or T1 the 13-bit count mode on the 80C51 (current
Mode 0) has been replaced in the XA with a 16-bit auto-reload
mode. Four additional 8-bit data registers (two per timer: RTHn and
RTLn) are created to hold the auto-reload values. In this mode, the
TH overflow will set the TF flag in the TCON register and cause both
the TL and TH counters to be loaded from the RTL and RTH
registers respectively.
Mode 2 operation is the same for Timer/Counter 0.
The overflow rate for Timer 0 or Timer 1 in Mode 2 may be
calculated as follows:
Timer_Rate = Osc / (N * (256 – Timer_Reload_Value))
where N = the TCLK prescaler value: 4, 16, or 64.
These new SFRs will also be used to hold the TL reload data in the
8-bit auto-reload mode (Mode 2) instead of TH.
Mode 3
Timer 1 in Mode 3 simply holds its count. The effect is the same as
setting TR1 = 0.
The overflow rate for Timer 0 or Timer 1 in Mode 0 may be
calculated as follows:
Timer 0 in Mode 3 establishes TL0 and TH0 as two separate
counters. TL0 uses the Timer 0 control bits C/T, GATE, TR0, and
TF0 as well as pin INT0. TH0 is locked into a timer function and
takes over the use of TR1 and TF1 from Timer 1. Thus, TH0 now
controls the “Timer 1” interrupt.
Timer_Rate = Osc / (N * (65536 – Timer_Reload_Value))
where N = the TCLK prescaler value: 4 (default), 16, or 64.
Mode 1
Mode 1 is the 16-bit non-auto reload mode.
Mode 3 is provided for applications requiring an extra 8-bit timer.
When Timer 0 is in Mode 3, Timer 1 can be turned on and off by
switching it out of and into its own Mode 3, or can still be used by
the serial port as a baud rate generator, or in fact, in any application
not requiring an interrupt.
Mode 2
Mode 2 configures the Timer register as an 8-bit Counter (TLn) with
automatic reload. Overflow from TLn not only sets TFn, but also
TCON
Address:410
Bit Addressable
Reset Value: 00H
BIT
TCON.7
SYMBOL
TF1
TCON.6
TCON.5
TR1
TF0
TCON.4
TCON.3
TR0
IE1
TCON.2
IT1
TCON.1
IE0
TCON.0
IT0
XA-G39
MSB
TF1
LSB
TR1
TF0
TR0
IE1
IT1
IE0
IT0
FUNCTION
Timer 1 overflow flag. Set by hardware on Timer/Counter overflow.
This flag will not be set if T1OE (TSTAT.2) is set.
Cleared by hardware when processor vectors to interrupt routine, or by clearing the bit in software.
Timer 1 Run control bit. Set/cleared by software to turn Timer/Counter 1 on/off.
Timer 0 overflow flag. Set by hardware on Timer/Counter overflow.
This flag will not be set if T0OE (TSTAT.0) is set.
Cleared by hardware when processor vectors to interrupt routine, or by clearing the bit in software.
Timer 0 Run control bit. Set/cleared by software to turn Timer/Counter 0 on/off.
Interrupt 1 Edge flag. Set by hardware when external interrupt edge detected.
Cleared when interrupt processed.
Interrupt 1 type control bit. Set/cleared by software to specify falling edge/low level triggered
external interrupts.
Interrupt 0 Edge flag. Set by hardware when external interrupt edge detected.
Cleared when interrupt processed.
Interrupt 0 Type control bit. Set/cleared by software to specify falling edge/low level
triggered external interrupts.
SU00604C
Figure 7. Timer/Counter Control (TCON) Register
2002 Mar 13
20
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
T2CON
Address:418
Bit Addressable
Reset Value: 00H
BIT
T2CON.7
T2CON.6
T2CON.5
T2CON.4
T2CON.3
T2CON.2
T2CON.1
T2CON.0
XA-G39
MSB
TF2
LSB
EXF2
RCLK0
TCLK0
EXEN2
TR2
C/T2
CP/RL2
SYMBOL FUNCTION
TF2
Timer 2 overflow flag. Set by hardware on Timer/Counter overflow. Must be cleared by software.
TF2 will not be set when RCLK0, RCLK1, TCLK0, TCLK1 or T2OE=1.
EXF2
Timer 2 external flag is set when a capture or reload occurs due to a negative transition on T2EX (and
EXEN2 is set). This flag will cause a Timer 2 interrupt when this interrupt is enabled. EXF2 is cleared by
software.
RCLK0
Receive Clock Flag.
TCLK0
Transmit Clock Flag. RCLK0 and TCLK0 are used to select Timer 2 overflow rate as a clock source for
UART0 instead of Timer T1.
EXEN2
Timer 2 external enable bit allows a capture or reload to occur due to a negative transition on T2EX.
TR2
Start=1/Stop=0 control for Timer 2.
C/T2
Timer or counter select.
0=Internal timer
1=External event counter (falling edge triggered)
CP/RL2
Capture/Reload flag.
If CP/RL2 & EXEN2=1 captures will occur on negative transitions of T2EX.
If CP/RL2=0, EXEN2=1 auto reloads occur with either Timer 2 overflows or negative transitions at T2EX.
If RCLK or TCLK=1 the timer is set to auto reload on Timer 2 overflow, this bit has no effect.
SU01592
Figure 8. Timer/Counter 2 Control (T2CON) Register
Auto-Reload Mode (Up or Down Counter)
In the auto-reload mode, the timer registers are loaded with the
16-bit value in T2CAPH and T2CAPL when the count overflows.
T2CAPH and T2CAPL are initialized by software. If the EXEN2 bit in
T2CON is set, the timer registers will also be reloaded and the EXF2
flag set when a 1-to-0 transition occurs at input T2EX. The
auto-reload mode is shown in Figure 12.
New Timer-Overflow Toggle Output
In the XA, the timer module now has two outputs, which toggle on
overflow from the individual timers. The same device pins that are
used for the T0 and T1 count inputs are also used for the new
overflow outputs. An SFR bit (TnOE in the TSTAT register) is
associated with each counter and indicates whether Port-SFR data
or the overflow signal is output to the pin. These outputs could be
used in applications for generating variable duty cycle PWM outputs
(changing the auto-reload register values). Also variable frequency
(Osc/8 to Osc/8,388,608) outputs could be achieved by adjusting
the prescaler along with the auto-reload register values. With a
30.0MHz oscillator, this range would be 3.58Hz to 3.75MHz.
In this mode, Timer 2 can be configured to count up or down. This is
done by setting or clearing the bit DCEN (Down Counter Enable) in
the T2MOD special function register (see Table 4). The T2EX pin
then controls the count direction. When T2EX is high, the count is in
the up direction, when T2EX is low, the count is in the down
direction.
Timer T2
Timer 2 in the XA is a 16-bit Timer/Counter which can operate as
either a timer or as an event counter. This is selected by C/T2 in the
special function register T2CON. Upon timer T2 overflow/underflow,
the TF2 flag is set, which may be used to generate an interrupt. It
can be operated in one of three operating modes: auto-reload (up or
down counting), capture, or as the baud rate generator (for either or
both UARTs via SFRs T2MOD and T2CON). These modes are
shown in Table 4.
Figure 12 shows Timer 2, which will count up automatically, since
DCEN = 0. In this mode there are two options selected by bit
EXEN2 in the T2CON register. If EXEN2 = 0, then Timer 2 counts
up to FFFFH and sets the TF2 (Overflow Flag) bit upon overflow.
This causes the Timer 2 registers to be reloaded with the 16-bit
value in T2CAPL and T2CAPH, whose values are preset by
software. If EXEN2 = 1, a 16-bit reload can be triggered either by an
overflow or by a 1-to-0 transition at input T2EX. This transition also
sets the EXF2 bit. If enabled, either TF2 or EXF2 bit can generate
the Timer 2 interrupt.
Capture Mode
In the capture mode there are two options which are selected by bit
EXEN2 in T2CON. If EXEN2 = 0, then timer 2 is a 16-bit timer or
counter, which upon overflowing sets bit TF2, the timer 2 overflow
bit. This will cause an interrupt when the timer 2 interrupt is enabled.
In Figure 13, the DCEN = 1; this enables the Timer 2 to count up or
down. In this mode, the logic level of T2EX pin controls the direction
of count. When a logic ‘1’ is applied at pin T2EX, the Timer 2 will
count up. The Timer 2 will overflow at FFFFH and set the TF2 flag,
which can then generate an interrupt if enabled. This timer overflow,
also causes the 16-bit value in T2CAPL and T2CAPH to be
reloaded into the timer registers TL2 and TH2, respectively.
If EXEN2 = 1, then Timer 2 still does the above, but with the added
feature that a 1-to-0 transition at external input T2EX causes the
current value in the Timer 2 registers, TL2 and TH2, to be captured
into registers RCAP2L and RCAP2H, respectively. In addition, the
transition at T2EX causes bit EXF2 in T2CON to be set. This will
cause an interrupt in the same fashion as TF2 when the Timer 2
interrupt is enabled. The capture mode is illustrated in Figure 11.
2002 Mar 13
A logic ‘0’ at pin T2EX causes Timer 2 to count down. When
counting down, the timer value is compared to the 16-bit value
contained in T2CAPH and T2CAPL. When the value is equal, the
21
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
timer register is loaded with FFFF hex. The underflow also sets the
TF2 flag, which can generate an interrupt if enabled.
Timer/Counter 2 or (2) to output a 50% duty cycle clock ranging from
3.58Hz to 3.75MHz at a 30MHz operating frequency.
The external flag EXF2 toggles when Timer 2 underflows or
overflows. This EXF2 bit can be used as a 17th bit of resolution, if
needed. the EXF2 flag does not generate an interrupt in this mode.
As the baud rate generator, timer T2 is incremented by TCLK.
To configure the Timer/Counter 2 as a clock generator, bit C/T2 (in
T2CON) must be cleared and bit T20E in T2MOD must be set. Bit
TR2 (T2CON.2) also must be set to start the timer.
The Clock-Out frequency depends on the oscillator frequency and
the reload value of Timer 2 capture registers (TCAP2H, TCAP2L) as
shown in this equation:
Baud Rate Generator Mode
By setting the TCLKn and/or RCLKn in T2CON or T2MOD, the
Timer 2 can be chosen as the baud rate generator for either or both
UARTs. The baud rates for transmit and receive can be
simultaneously different.
2
TCLK
(65536 * TCAP2H, TCAP2L)
In the Clock-Out mode Timer 2 roll-overs will not generate an
interrupt. This is similar to when it is used as a baud-rate generator.
It is possible to use Timer 2 as a baud-rate generator and a clock
generator simultaneously. Note, however, that the baud-rate will be
1/8 of the Clock-Out frequency.
Programmable Clock-Out
A 50% duty cycle clock can be programmed to come out on P1.6.
This pin, besides being a regular I/O pin, has two alternate
functions. It can be programmed (1) to input the external clock for
Table 4. Timer 2 Operating Modes
TR2
CP/RL2
RCLK+TCLK
DCEN
0
X
X
X
Timer off (stopped)
1
0
0
0
16-bit auto-reload, counting up
1
0
0
1
16-bit auto-reload, counting up or down depending on T2EX pin
1
1
0
X
16-bit capture
1
X
1
X
Baud rate generator
TSTAT
Address:411
Bit Addressable
Reset Value: 00H
BIT
TSTAT.2
SYMBOL
T1OE
TSTAT.0
T0OE
MODE
MSB
—
LSB
—
—
—
—
T1OE
—
T0OE
FUNCTION
When 0, this bit allows the T1 pin to clock Timer 1 when in the counter mode.
When 1, T1 acts as an output and toggles at every Timer 1 overflow.
When 0, this bit allows the T0 pin to clock Timer 0 when in the counter mode.
When 1, T0 acts as an output and toggles at every Timer 0 overflow.
SU00612B
Figure 9. Timer 0 And 1 Extended Status (TSTAT)
T2MOD
Address:419
Bit Addressable
Reset Value: 00H
MSB
—
LSB
—
RCLK1
TCLK1
—
—
T2OE
DCEN
BIT
SYMBOL FUNCTION
T2MOD.5 RCLK1
Receive Clock Flag.
T2MOD.4 TCLK1
Transmit Clock Flag. RCLK1 and TCLK1 are used to select Timer 2 overflow rate as a clock source
for UART1 instead of Timer T1.
T2MOD.1 T2OE
When 0, this bit allows the T2 pin to clock Timer 2 when in the counter mode.
When 1, T2 acts as an output and toggles at every Timer 2 overflow.
T2MOD.0 DCEN
Controls count direction for Timer 2 in autoreload mode.
DCEN=0 counter set to count up only
DCEN=1 counter set to count up or down, depending on T2EX (see text).
SU00610B
Figure 10. Timer 2 Mode Control (T2MOD)
2002 Mar 13
22
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
TCLK
XA-G39
C/T2 = 0
TL2
(8-bits)
TH2
(8-bits)
TF2
C/T2 = 1
T2 Pin
Control
Transition
Detector
TR2
Capture
Timer 2
Interrupt
T2CAPL
T2CAPH
T2EX Pin
EXF2
Control
EXEN2
SU00704
Figure 11. Timer 2 in Capture Mode
TCLK
C/T2 = 0
TL2
(8-bits)
TH2
(8-bits)
C/T2 = 1
T2 Pin
Control
TR2
Reload
Transition
Detector
T2CAPL
T2CAPH
TF2
Timer 2
Interrupt
T2EX Pin
EXF2
Control
EXEN2
SU00705
Figure 12. Timer 2 in Auto-Reload Mode (DCEN = 0)
(DOWN COUNTING RELOAD VALUE)
FFH
FFH
TOGGLE
EXF2
TCLK
C/T2 = 0
OVERFLOW
TL2
T2 PIN
TH2
TF2
INTERRUPT
C/T2 = 1
CONTROL
TR2
COUNT
DIRECTION
1 = UP
0 = DOWN
T2CAPL
T2CAPH
(UP COUNTING RELOAD VALUE)
Figure 13. Timer 2 Auto Reload Mode (DCEN = 1)
2002 Mar 13
23
T2EX PIN
SU00706
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
The software must be written so that a feed operation takes place
every tD seconds from the last feed operation. Some tradeoffs may
need to be made. It is not advisable to include feed operations in
minor loops or in subroutines unless the feed operation is a specific
subroutine.
WATCHDOG TIMER
The watchdog timer subsystem protects the system from incorrect
code execution by causing a system reset when the watchdog timer
underflows as a result of a failure of software to feed the timer prior
to the timer reaching its terminal count. It is important to note that
the watchdog timer is running after any type of reset and must be
turned off by user software if the application does not use the
watchdog function.
To turn the watchdog timer completely off, the following code
sequence should be used:
mov.b
mov.b
mov.b
Watchdog Function
The watchdog consists of a programmable prescaler and the main
timer. The prescaler derives its clock from the TCLK source that also
drives timers 0, 1, and 2. The watchdog timer subsystem consists of
a programmable 13-bit prescaler, and an 8-bit main timer. The main
timer is clocked (decremented) by a tap taken from one of the top
8-bits of the prescaler as shown in Figure 14. The clock source for
the prescaler is the same as TCLK (same as the clock source for
the timers). Thus the main counter can be clocked as often as once
every 32 TCLKs (see Table 5). The watchdog generates an
underflow signal (and is autoloaded from WDL) when the watchdog
is at count 0 and the clock to decrement the watchdog occurs. The
watchdog is 8 bits wide and the autoload value can range from 0 to
FFH. (The autoload value of 0 is permissible since the prescaler is
cleared upon autoload).
Watchdog Control Register (WDCON)
The reset values of the WDCON and WDL registers will be such that
the watchdog timer has a timeout period of 4 × 4096 × tOSC and the
watchdog is running. WDCON can be written by software but the
changes only take effect after executing a valid watchdog feed
sequence.
Table 5. Prescaler Select Values in WDCON
tMIN = tOSC × 4 × 32 (W = 0, N = 4)
tMAX = tOSC × 64 × 4096 × 256 (W = 255, N = 64)
tD = tOSC × N × P × (W + 1)
The watchdog timer is not directly loadable by the user. Instead, the
value to be loaded into the main timer is held in an autoload register.
In order to cause the main timer to be loaded with the appropriate
value, a special sequence of software action must take place. This
operation is referred to as feeding the watchdog timer.
PRE1
PRE0
DIVISOR
0
0
0
32
0
0
1
64
0
1
0
128
0
1
1
256
1
0
0
512
1
0
1
1024
1
1
0
2048
1
1
1
4096
When external reset is applied, the following takes place:
• Watchdog run control bit set to ON (1).
• Autoload register WDL set to 00 (min. count).
• Watchdog time-out flag cleared.
• Prescaler is cleared.
• Prescaler tap set to the highest divide.
• Autoload takes place.
; disable global interrupts.
; do watchdog feed part 1
; do watchdog feed part 2
; re-enable global interrupts.
When coming out of a hardware reset, the software should load the
autoload register and then feed the watchdog (cause an autoload).
This sequence assumes that the XA interrupt system is enabled and
there is a possibility of an interrupt request occurring during the feed
sequence. If an interrupt was allowed to be serviced and the service
routine contained any SFR access, it would trigger a watchdog
reset. If it is known that no interrupt could occur during the feed
sequence, the instructions to disable and re-enable interrupts may
be removed.
2002 Mar 13
PRE2
Watchdog Detailed Operation
To feed the watchdog, two instructions must be sequentially
executed successfully. No intervening SFR accesses are allowed,
so interrupts should be disabled before feeding the watchdog. The
instructions should move A5H to the WFEED1 register and then
5AH to the WFEED2 register. If WFEED1 is correctly loaded and
WFEED2 is not correctly loaded, then an immediate watchdog reset
will occur. The program sequence to feed the watchdog timer or
cause new WDCON settings to take effect is as follows:
ea
wfeed1,#A5h
wfeed2,#5Ah
ea
wdcon,#0
; set WD control register to clear WDRUN.
wfeed1,#A5h ; do watchdog feed part 1
wfeed2,#5Ah ; do watchdog feed part 2
This sequence assumes that the watchdog timer is being turned off
at the beginning of initialization code and that the XA interrupt
system has not yet been enabled. If the watchdog timer is to be
turned off at a point when interrupts may be enabled, instructions to
disable and re-enable interrupts should be added to this sequence.
This leads to the following user design equations. Definitions: tOSC
is the oscillator period, N is the selected prescaler tap value, W is
the main counter autoload value, P is the prescaler value from
Table 5, tMIN is the minimum watchdog time-out value (when the
autoload value is 0), tMAX is the maximum time-out value (when the
autoload value is FFH), tD is the design time-out value.
clr
mov.b
mov.b
setb
XA-G39
If the watchdog is running and happens to underflow at the time the
external reset is applied, the watchdog time-out flag will be cleared.
24
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
WDL
WATCHDOG FEED SEQUENCE
MOV WFEED1,#A5H
MOV WFEED2,#5AH
TCLK
8–BIT DOWN
COUNTER
PRESCALER
PRE2
PRE1
PRE0
—
—
WDRUN
INTERNAL RESET
WDTOF
—
WDCON
SU00581A
Figure 14. Watchdog Timer in XA-G39
Each UART baud rate is determined by either a fixed division of the
oscillator (in UART modes 0 and 2) or by the timer 1 or timer 2
overflow rate (in UART modes 1 and 3).
When the watchdog underflows, the following action takes place
(see Figure 14):
• Autoload takes place.
• Watchdog time-out flag is set
• Watchdog run bit unchanged.
• Autoload (WDL) register unchanged.
• Prescaler tap unchanged.
• All other device action same as external reset.
Timer 1 defaults to clock both UART0 and UART1. Timer 2 can be
programmed to clock either UART0 through T2CON (via bits R0CLK
and T0CLK) or UART1 through T2MOD (via bits R1CLK and
T1CLK). In this case, the UART not clocked by T2 could use T1 as
the clock source.
The serial port receive and transmit registers are both accessed at
Special Function Register SnBUF. Writing to SnBUF loads the
transmit register, and reading SnBUF accesses a physically
separate receive register.
Note that if the watchdog underflows, the program counter will be
loaded from the reset vector as in the case of an internal reset. The
watchdog time-out flag can be examined to determine if the
watchdog has caused the reset condition. The watchdog time-out
flag bit can be cleared by software.
The serial port can operate in 4 modes:
Mode 0: Serial I/O expansion mode. Serial data enters and exits
through RxDn. TxDn outputs the shift clock. 8 bits are
transmitted/received (LSB first). (The baud rate is fixed at 1/16 the
oscillator frequency.)
WDCON Register Bit Definitions
WDCON.7 PRE2
Prescaler Select 2, reset to 1
WDCON.6 PRE1
Prescaler Select 1, reset to 1
WDCON.5 PRE0
Prescaler Select 0, reset to 1
WDCON.4 —
WDCON.3 —
WDCON.2 WDRUN Watchdog Run Control bit, reset to 1
WDCON.1 WDTOF
Timeout flag
WDCON.0 —
Mode 1: Standard 8-bit UART mode. 10 bits are transmitted
(through TxDn) or received (through RxDn): a start bit (0), 8 data
bits (LSB first), and a stop bit (1). On receive, the stop bit goes into
RB8 in Special Function Register SnCON. The baud rate is variable.
Mode 2: Fixed rate 9-bit UART mode. 11 bits are transmitted
(through TxD) or received (through RxD): start bit (0), 8 data bits
(LSB first), a programmable 9th data bit, and a stop bit (1). On
Transmit, the 9th data bit (TB8_n in SnCON) can be assigned the
value of 0 or 1. Or, for example, the parity bit (P, in the PSW) could
be moved into TB8_n. On receive, the 9th data bit goes into RB8_n
in Special Function Register SnCON, while the stop bit is ignored.
The baud rate is programmable to 1/32 of the oscillator frequency.
UARTs
The XA-G39 includes 2 UART ports that are compatible with the
enhanced UART used on the 8xC51Fx, 8xC51Rx+, 8xC51Rx2, and
8xC51Mx2. Baud rate selection is somewhat different due to the
clocking scheme used for the XA timers.
Mode 3: Standard 9-bit UART mode. 11 bits are transmitted
(through TxDn) or received (through RxDn): a start bit (0), 8 data
bits (LSB first), a programmable 9th data bit, and a stop bit (1).
In fact, Mode 3 is the same as Mode 2 in all respects except baud
rate. The baud rate in Mode 3 is variable.
Some other enhancements have been made to UART operation.
The first is that there are separate interrupt vectors for each UART’s
transmit and receive functions. The UART transmitter has been
double buffered, allowing packed transmission of data with no gaps
between bytes and less critical interrupt service routine timing. A
break detect function has been added to the UART. This operates
independently of the UART itself and provides a start-of-break status
bit that the program may test. Finally, an Overrun Error flag has
been added to detect missed characters in the received data
stream. The double buffered UART transmitter may require some
software changes in code written for the original XA-G39 single
buffered UART.
2002 Mar 13
In all four modes, transmission is initiated by any instruction that
uses SnBUF as a destination register. Reception is initiated in
Mode 0 by the condition RI_n = 0 and REN_n = 1. Reception is
initiated in the other modes by the incoming start bit if REN_n = 1.
25
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
message has been transmitted completely. The interrupt service
routine should handle this additional interrupt.
Serial Port Control Register
The serial port control and status register is the Special Function
Register SnCON, shown in Figure 16. This register contains not only
the mode selection bits, but also the 9th data bit for transmit and
receive (TB8_n and RB8_n), and the serial port interrupt bits (TI_n
and RI_n).
The recommended method of using the double buffering in the
application program is to have the interrupt service routine handle a
single byte for each interrupt occurrence. In this manner the
program essentially does not require any special considerations for
double buffering. Unless higher priority interrupts cause delays in
the servicing of the UART transmitter interrupt, the double buffering
will result in transmitted bytes being tightly packed with no
intervening gaps.
TI Flag
In order to allow easy use of the double buffered UART transmitter
feature, the TI_n flag is set by the UART hardware under two
conditions. The first condition is the completion of any byte
transmission. This occurs at the end of the stop bit in modes 1, 2, or
3, or at the end of the eighth data bit in mode 0. The second
condition is when SnBUF is written while the UART transmitter is
idle. In this case, the TI_n flag is set in order to indicate that the
second UART transmitter buffer is still available.
9-bit Mode
Please note that the ninth data bit (TB8) is not double buffered. Care
must be taken to insure that the TB8 bit contains the intended data
at the point where it is transmitted. Double buffering of the UART
transmitter may be bypassed as a simple means of synchronizing
TB8 to the rest of the data stream.
Typically, UART transmitters generate one interrupt per byte
transmitted. In the case of the XA UART, one additional interrupt is
generated as defined by the stated conditions for setting the TI_n
flag. This additional interrupt does not occur if double buffering is
bypassed as explained below. Note that if a character oriented
approach is used to transmit data through the UART, there could be
a second interrupt for each character transmitted, depending on the
timing of the writes to SBUF. For this reason, it is generally better to
bypass double buffering when the UART transmitter is used in
character oriented mode. This is also true if the UART is polled
rather than interrupt driven, and when transmission is character
oriented rather than message or string oriented. The interrupt occurs
at the end of the last byte transmitted when the UART becomes idle.
Among other things, this allows a program to determine when a
2002 Mar 13
XA-G39
Bypassing Double Buffering
The UART transmitter may be used as if it is single buffered. The
recommended UART transmitter interrupt service routine (ISR)
technique to bypass double buffering first clears the TI_n flag upon
entry into the ISR, as in standard practice. This clears the interrupt
that activated the ISR. Secondly, the TI_n flag is cleared
immediately following each write to SnBUF. This clears the interrupt
flag that would otherwise direct the program to write to the second
transmitter buffer. If there is any possibility that a higher priority
interrupt might become active between the write to SnBUF and the
clearing of the TI_n flag, the interrupt system may have to be
temporarily disabled during that sequence by clearing, then setting
the EA bit in the IEL register.
26
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
CLOCKING SCHEME/BAUD RATE GENERATION
Using Timer 2 to Generate Baud Rates
The XA UARTS clock rates are determined by either a fixed division
(modes 0 and 2) of the oscillator clock or by the Timer 1 or Timer 2
overflow rate (modes 1 and 3).
Timer T2 is a 16-bit up/down counter in XA. As a baud rate
generator, timer 2 is selected as a clock source for either/both
UART0 and UART1 transmitters and/or receivers by setting TCLKn
and/or RCLKn in T2CON and T2MOD. As the baud rate generator,
T2 is incremented as Osc/N where N = 4, 16 or 64 depending on
TCLK as programmed in the SCR bits PT1, and PTO. So, if T2 is
the source of one UART, the other UART could be clocked by either
T1 overflow or fixed clock, and the UARTs could run independently
with different baud rates.
The clock for the UARTs in XA runs at 16x the Baud rate. If the
timers are used as the source for Baud Clock, since maximum
speed of timers/Baud Clock is Osc/4, the maximum baud rate is
timer overflow divided by 16 i.e. Osc/64.
In Mode 0, it is fixed at Osc/16. In Mode 2, however, the fixed rate is
Osc/32.
Pre-scaler
f allll Ti
for
Timers T0
T0,1,2
12
controlled by PT1, PT0
bits in SCR
00
Osc/4
01
Osc/16
10
Osc/64
11
reserved
T2CON
0x418
T2MOD
0x419
Baud Rate for UART Mode 0:
Baud_Rate = Osc/16
bit5
bit4
RCLK0
TCLK0
bit5
bit4
RCLK1
TCLK1
Prescaler Select for Timer Clock (TCLK)
Baud Rate calculation for UART Mode 1 and 3:
Baud_Rate = Timer_Rate/16
SCR
0x440
bit3
bit2
PT1
PT0
Timer_Rate = Osc/(N*(Timer_Range– Timer_Reload_Value))
where N = the TCLK prescaler value: 4, 16, or 64.
and Timer_Range = 256 for timer 1 in mode 2.
65536 for timer 1 in mode 0 and timer 2
in count up mode.
The timer reload value may be calculated as follows:
Timer_Reload_Value = Timer_Range–(Osc/(Baud_Rate*N*16))
NOTES:
1. The maximum baud rate for a UART in mode 1 or 3 is Osc/64.
2. The lowest possible baud rate (for a given oscillator frequency
and N value) may be found by using a timer reload value of 0.
3. The timer reload value may never be larger than the timer range.
4. If a timer reload value calculation gives a negative or fractional
result, the baud rate requested is not possible at the given
oscillator frequency and N value.
Baud Rate for UART Mode 2:
Baud_Rate = Osc/32
SnSTAT Address: S0STAT 421
S1STAT 425
Bit Addressable
Reset Value: 00H
MSB
—
LSB
—
—
—
FEn
BRn
OEn
STINTn
BIT
SYMBOL FUNCTION
SnSTAT.3 FEn
Framing Error flag is set when the receiver fails to see a valid STOP bit at the end of the frame.
Cleared by software.
SnSTAT.2 BRn
Break Detect flag is set if a character is received with all bits (including STOP bit) being logic ‘0’. Thus
it gives a “Start of Break Detect” on bit 8 for Mode 1 and bit 9 for Modes 2 and 3. The break detect
feature operates independently of the UARTs and provides the START of Break Detect status bit that
a user program may poll. Cleared by software.
SnSTAT.1 OEn
Overrun Error flag is set if a new character is received in the receiver buffer while it is still full (before
the software has read the previous character from the buffer), i.e., when bit 8 of a new byte is
received while RI in SnCON is still set. Cleared by software.
SnSTAT.0 STINTn
This flag must be set to enable any of the above status flags to generate a receive interrupt (RIn). The
only way it can be cleared is by a software write to this register.
SU00607B
Figure 15. Serial Port Extended Status (SnSTAT) Register
(See also Figure 17 regarding Framing Error flag)
2002 Mar 13
27
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
A0H – A3H
UART 0 Receiver
7
A4H – A7H
UART 0 Transmitter
8
Given slave address or addresses. All of the slaves may be
contacted by using the Broadcast address. Two special Function
Registers are used to define the slave’s address, SADDR, and the
address mask, SADEN. SADEN is used to define which bits in the
SADDR are to be used and which bits are “don’t care”. The SADEN
mask can be logically ANDed with the SADDR to create the “Given”
address which the master will use for addressing each of the slaves.
Use of the Given address allows multiple slaves to be recognized
while excluding others. The following examples will help to show the
versatility of this scheme:
A8H – ABH
UART 1 Receiver
9
Slave 0
ACH – AFH
UART 1 Transmitter
10
SADDR =
SADEN =
Given
=
1100 0000
1111 1101
1100 00X0
Slave 1
SADDR =
SADEN =
Given
=
1100 0000
1111 1110
1100 000X
UART INTERRUPT SCHEME
There are separate interrupt vectors for each UART’s transmit and
receive functions.
Table 6. Vector Locations for UARTs in XA
Vector Address
Interrupt Source
Arbitration
NOTE:
The transmit and receive vectors could contain the same ISR
address to work like a 8051 interrupt scheme
Error Handling, Status Flags and Break Detect
The UARTs in XA has the following error flags; see Figure 15.
In the above example SADDR is the same and the SADEN data is
used to differentiate between the two slaves. Slave 0 requires a 0 in
bit 0 and it ignores bit 1. Slave 1 requires a 0 in bit 1 and bit 0 is
ignored. A unique address for Slave 0 would be 1100 0010 since
slave 1 requires a 0 in bit 1. A unique address for slave 1 would be
1100 0001 since a 1 in bit 0 will exclude slave 0. Both slaves can be
selected at the same time by an address which has bit 0 = 0 (for
slave 0) and bit 1 = 0 (for slave 1). Thus, both could be addressed
with 1100 0000.
Multiprocessor Communications
Modes 2 and 3 have a special provision for multiprocessor
communications. In these modes, 9 data bits are received. The 9th
one goes into RB8. Then comes a stop bit. The port can be
programmed such that when the stop bit is received, the serial port
interrupt will be activated only if RB8 = 1. This feature is enabled by
setting bit SM2 in SCON. A way to use this feature in multiprocessor
systems is as follows:
In a more complex system the following could be used to select
slaves 1 and 2 while excluding slave 0:
When the master processor wants to transmit a block of data to one
of several slaves, it first sends out an address byte which identifies
the target slave. An address byte differs from a data byte in that the
9th bit is 1 in an address byte and 0 in a data byte. With SM2 = 1, no
slave will be interrupted by a data byte. An address byte, however,
will interrupt all slaves, so that each slave can examine the received
byte and see if it is being addressed. The addressed slave will clear
its SM2 bit and prepare to receive the data bytes that will be coming.
The slaves that weren’t being addressed leave their SM2s set and
go on about their business, ignoring the coming data bytes.
SM2 has no effect in Mode 0, and in Mode 1 can be used to check
the validity of the stop bit although this is better done with the
Framing Error (FE) flag. In a Mode 1 reception, if SM2 = 1, the
receive interrupt will not be activated unless a valid stop bit is
received.
SADDR =
SADEN =
Given
=
1100 0000
1111 1001
1100 0XX0
Slave 1
SADDR =
SADEN =
Given
=
1110 0000
1111 1010
1110 0X0X
Slave 2
SADDR =
SADEN =
Given
=
1110 0000
1111 1100
1110 00XX
In the above example the differentiation among the 3 slaves is in the
lower 3 address bits. Slave 0 requires that bit 0 = 0 and it can be
uniquely addressed by 1110 0110. Slave 1 requires that bit 1 = 0 and
it can be uniquely addressed by 1110 and 0101. Slave 2 requires
that bit 2 = 0 and its unique address is 1110 0011. To select Slaves 0
and 1 and exclude Slave 2 use address 1110 0100, since it is
necessary to make bit 2 = 1 to exclude slave 2.
Automatic Address Recognition
Automatic Address Recognition is a feature which allows the UART
to recognize certain addresses in the serial bit stream by using
hardware to make the comparisons. This feature saves a great deal
of software overhead by eliminating the need for the software to
examine every serial address which passes by the serial port. This
feature is enabled by setting the SM2 bit in SCON. In the 9 bit UART
modes, mode 2 and mode 3, the Receive Interrupt flag (RI) will be
automatically set when the received byte contains either the “Given”
address or the “Broadcast” address. The 9 bit mode requires that
the 9th information bit is a 1 to indicate that the received information
is an address and not data. Automatic address recognition is shown
in Figure 18.
The Broadcast Address for each slave is created by taking the
logical OR of SADDR and SADEN. Zeros in this result are teated as
don’t-cares. In most cases, interpreting the don’t-cares as ones, the
broadcast address will be FF hexadecimal.
Upon reset SADDR and SADEN are loaded with 0s. This produces
a given address of all “don’t cares” as well as a Broadcast address
of all “don’t cares”. This effectively disables the Automatic
Addressing mode and allows the microcontroller to use standard
UART drivers which do not make use of this feature.
Using the Automatic Address Recognition feature allows a master to
selectively communicate with one or more slaves by invoking the
2002 Mar 13
Slave 0
28
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
SnCON
Address:
S0CON 420
S1CON 424
XA-G39
MSB
LSB
SM0
Bit Addressable
Reset Value: 00H
SM1
SM2
REN
TB8
RB8
TI
RI
Where SM0, SM1 specify the serial port mode, as follows:
SM0
0
0
1
1
SM1
0
1
0
1
Mode
0
1
2
3
Description
shift register
8-bit UART
9-bit UART
9-bit UART
Baud Rate
fOSC/16
variable
fOSC/32
variable
BIT
SYMBOL FUNCTION
SnCON.5 SM2
Enables the multiprocessor communication feature in Modes 2 and 3. In Mode 2 or 3, if SM2 is set to 1, then RI
will not be activated if the received 9th data bit (RB8) is 0. In Mode 1, if SM2=1 then RI will not be activated if a
valid stop bit was not received. In Mode 0, SM2 should be 0.
SnCON.4 REN
Enables serial reception. Set by software to enable reception. Clear by software to disable reception.
SnCON.3 TB8
The 9th data bit that will be transmitted in Modes 2 and 3. Set or clear by software as desired. The TB8 bit is not
double buffered. See text for details.
SnCON.2 RB8
In Modes 2 and 3, is the 9th data bit that was received. In Mode 1, if SM2=0, RB8 is the stop bit that was
received. In Mode 0, RB8 is not used.
SnCON.1 TI
Transmit interrupt flag. Set when another byte may be written to the UART transmitter. See text for details.
Must be cleared by software.
SnCON.0 RI
Receive interrupt flag. Set by hardware at the end of the 8th bit time in Mode 0, or at the end of the stop bit time
in the other modes (except see SM2). Must be cleared by software.
SU00597C
Figure 16. Serial Port Control (SnCON) Register
D0
D1
D2
D3
D4
D5
D6
D7
D8
DATA BYTE
START
BIT
ONLY IN
MODE 2, 3
STOP
BIT
if 0, sets FE
—
—
—
—
FEn
BRn
OEn
STINTn
SnSTAT
SU00598
Figure 17. UART Framing Error Detection
D0
D1
D2
D3
SM0_n
1
1
D4
SM1_n
D5
D6
SM2_n
REN_n
TB8_n
1
X
1
1
0
D7
D8
RB8_n
TI_n
RI_n
SnCON
RECEIVED ADDRESS D0 TO D7
COMPARATOR
PROGRAMMED ADDRESS
IN UART MODE 2 OR MODE 3 AND SM2 = 1:
INTERRUPT IF REN=1, RB8=1 AND “RECEIVED ADDRESS” = “PROGRAMMED ADDRESS”
– WHEN OWN ADDRESS RECEIVED, CLEAR SM2 TO RECEIVE DATA BYTES
– WHEN ALL DATA BYTES HAVE BEEN RECEIVED: SET SM2 TO WAIT FOR NEXT ADDRESS.
SU00613
Figure 18. UART Multiprocessor Communication, Automatic Address Recognition
2002 Mar 13
29
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
the address contained in the memory location 0000h. The
destination of the reset jump must be located in the first 64 K of
code address on power-up, all vectors are 16-bit values and so point
to page zero addresses only. After a reset the RAM contents are
indeterminate.
I/O PORT OUTPUT CONFIGURATION
Each I/O port pin can be user configured to one of 4 output types.
The types are Quasi-bidirectional (essentially the same as standard
80C51 family I/O ports), Open-Drain, Push-Pull, and Off (high
impedance). The default configuration after reset is
Quasi-bidirectional. However, in the ROMless mode (the EA pin is
low at reset), the port pins that comprise the external data bus will
default to push-pull outputs.
Alternatively, the Boot Vector may supply the reset address. This
happens when use of the Boot Vector is forced or when the Flash
status byte is non-zero. These cases are described in the section
“Hardware Activation of the Boot Vector” on page 11.
I/O port output configurations are determined by the settings in port
configuration SFRs. There are 2 SFRs for each port, called
PnCFGA and PnCFGB, where “n” is the port number. One bit in
each of the 2 SFRs relates to the output setting for the
corresponding port pin, allowing any combination of the 2 output
types to be mixed on those port pins. For instance, the output type
of port 1 pin 3 is controlled by the setting of bit 3 in the SFRs
P1CFGA and P1CFGB.
VDD
R
XA
RST
C
Table 7 shows the configuration register settings for the 4 port
output types. The electrical characteristics of each output type may
be found in the DC Characteristic table.
SOME TYPICAL VALUES FOR R AND C:
R = 100K, C = 1.0 µF
R = 1.0M, C = 0.1 µF
(ASSUMING THAT THE VDD RISE TIME IS 1ms OR LESS)
Table 7. Port Configuration Register Settings
PnCFGB
PnCFGA
0
0
Open Drain
0
1
Quasi-bidirectional
1
0
Off (high impedance)
1
1
Push-Pull
Figure 19. Recommended Reset Circuit
Port Output Mode
RESET OPTIONS
The EA pin is sampled on the rising edge of the RST pulse, and
determines whether the device is to begin execution from internal or
external code memory. EA pulled high configures the XA in
single-chip mode. If EA is driven low, the device enters ROMless
mode. After Reset is released, the EA/WAIT pin becomes a bus wait
signal for external bus transactions.
NOTE:
Mode changes may cause glitches to occur during transitions. When
modifying both registers, WRITE instructions should be carried out
consecutively.
The BUSW/P3.5 pin is weakly pulled high while reset is asserted,
allowing simple biasing of the pin with a resistor to ground to select
the alternate bus width. If the BUSW pin is not driven at reset, the
weak pullup will cause a 1 to be loaded for the bus width, giving a
16-bit external bus. BUSW may be pulled low with a 2.7 K or smaller
value resistor, giving an 8-bit external bus. The bus width setting
from the BUSW pin may be overridden by software once the user
program is running.
EXTERNAL BUS
The external program/data bus allows for 8-bit or 16-bit bus width,
and address sizes from 12 to 20 bits. The bus width is selected by
an input at reset (see Reset Options below), while the address size
is set by the program in a configuration register. If all off-chip code is
selected (through the use of the EA pin), the initial code fetches will
be done with the maximum address size (20 bits).
Both EA and BUSW must be held for three oscillator clock times
after reset is deasserted to guarantee that their values are latched
correctly.
RESET
The device is reset whenever a logic “0“ is applied to RST for at
least 10 microseconds, placing a low level on the pin re-initializes
the on-chip logic. Reset must be asserted when power is initially
applied to the XA and held until the oscillator is running.
POWER REDUCTION MODES
The XA-G39 supports Idle and Power Down modes of power
reduction. The idle mode leaves some peripherals running to allow
them to wake up the processor when an interrupt is generated. The
power down mode stops the oscillator in order to minimize power.
The processor can be made to exit power down mode via reset or
one of the external interrupt inputs. In order to use an external
interrupt to re-activate the XA while in power down mode, the
external interrupt must be enabled and be configured to level
sensitive mode. In power down mode, the power supply voltage may
be reduced to the RAM keep-alive voltage (2 V), retaining the RAM,
register, and SFR values at the point where the power down mode
was entered.
The duration of reset must be extended when power is initially
applied or when using reset to exit power down mode. This is due to
the need to allow the oscillator time to start up and stabilize. For
most power supply ramp up conditions, this time is 10 milliseconds.
To provide a reliable reset during momentary power supply
interruption or whenever the power supply voltage drops below the
specified operating voltage, it is recommended that a CMOS system
reset circuit SA56614-XX or similar device be used, see application
note AN468.
As RST is brought high again, an exception is generated which
causes the processor to jump to the reset address. Typically, this is
2002 Mar 13
SU00702
30
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
The XA-G39 supports a total of 9 maskable event interrupt sources
(for the various XA peripherals), seven software interrupts, 5
exception interrupts (plus reset), and 16 traps. The maskable event
interrupts share a global interrupt disable bit (the EA bit in the IEL
register) and each also has a separate individual interrupt enable bit
(in the IEL or IEH registers). Only three bits of the IPA register
values are used on the XA-G39. Each event interrupt can be set to
occur at one of 8 priority levels via bits in the Interrupt Priority (IP)
registers, IPA0 through IPA5. The value 0 in the IPA field gives the
interrupt priority 0, in effect disabling the interrupt. A value of 1 gives
the interrupt a priority of 9, the value 2 gives priority 10, etc. The
result is the same as if all four bits were used and the top bit set for
all values except 0. Details of the priority scheme may be found in
the XA User Guide.
INTERRUPTS
The XA-G39 supports 38 vectored interrupt sources. These include
9 maskable event interrupts, 7 exception interrupts, 16 trap
interrupts, and 7 software interrupts. The maskable interrupts each
have 8 priority levels and may be globally and/or individually enabled
or disabled.
The XA defines four types of interrupts:
• Exception Interrupts – These are system level errors and other
very important occurrences which include stack overflow,
divide-by-0, and reset.
• Event interrupts – These are peripheral interrupts from devices
such as UARTs, timers, and external interrupt inputs.
• Software Interrupts – These are equivalent of hardware
The complete interrupt vector list for the XA-G39, including all 4
interrupt types, is shown in the following tables. The tables include
the address of the vector for each interrupt, the related priority
register bits (if any), and the arbitration ranking for that interrupt
source. The arbitration ranking determines the order in which
interrupts are processed if more than one interrupt of the same
priority occurs simultaneously.
interrupt, but are requested only under software control.
• Trap Interrupts – These are TRAP instructions, generally used to
call system services in a multi-tasking system.
Exception interrupts, software interrupts, and trap interrupts are
generally standard for XA derivatives and are detailed in the XA
User Guide. Event interrupts tend to be different on different XA
derivatives.
Table 8. Interrupt Vectors
EXCEPTION/TRAPS PRECEDENCE
VECTOR ADDRESS
ARBITRATION RANKING
Reset (h/w, watchdog, s/w)
DESCRIPTION
0000–0003
0 (High)
Breakpoint (h/w trap 1)
0004–0007
1
Trace (h/w trap 2)
0008–000B
1
Stack Overflow (h/w trap 3)
000C–000F
1
Divide by 0 (h/w trap 4)
0010–0013
1
User RETI (h/w trap 5)
0014–0017
1
TRAP 0– 15 (software)
0040–007F
1
EVENT INTERRUPTS
FLAG BIT
VECTOR
ADDRESS
ENABLE BIT
INTERRUPT PRIORITY
ARBITRATION
RANKING
External interrupt 0
IE0
0080–0083
EX0
IPA0.2–0 (PX0)
2
Timer 0 interrupt
TF0
0084–0087
ET0
IPA0.6–4 (PT0)
3
DESCRIPTION
External interrupt 1
IE1
0088–008B
EX1
IPA1.2–0 (PX1)
4
Timer 1 interrupt
TF1
008C–008F
ET1
IPA1.6–4 (PT1)
5
Timer 2 interrupt
TF2(EXF2)
0090–0093
ET2
IPA2.2–0 (PT2)
6
Serial port 0 Rx
RI.0
00A0–00A3
ERI0
IPA4.2–0 (PRIO)
7
Serial port 0 Tx
TI.0
00A4–00A7
ETI0
IPA4.6–4 (PTIO)
8
Serial port 1 Rx
RI.1
00A8–00AB
ERI1
IPA5.2–0 (PRT1)
9
Serial port 1 Tx
TI.1
00AC–00AF
ETI1
IPA5.6–4 (PTI1)
10
FLAG BIT
VECTOR
ADDRESS
ENABLE BIT
INTERRUPT PRIORITY
Software interrupt 1
SWR1
0100–0103
SWE1
(fixed at 1)
Software interrupt 2
SWR2
0104–0107
SWE2
(fixed at 2)
Software interrupt 3
SWR3
0108–010B
SWE3
(fixed at 3)
Software interrupt 4
SWR4
010C–010F
SWE4
(fixed at 4)
Software interrupt 5
SWR5
0110–0113
SWE5
(fixed at 5)
Software interrupt 6
SWR6
0114–0117
SWE6
(fixed at 6)
Software interrupt 7
SWR7
0118–011B
SWE7
(fixed at 7)
SOFTWARE INTERRUPTS
DESCRIPTION
2002 Mar 13
31
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
ABSOLUTE MAXIMUM RATINGS
PARAMETER
RATING
UNIT
Operating temperature under bias
–55 to +125
°C
Storage temperature range
–65 to +150
°C
0 to +13.0
V
Voltage on EA/VPP pin to VSS
Voltage on any other pin to VSS
–0.5 to VDD+0.5 V
V
Maximum IOL per I/O pin
15
mA
Power dissipation (based on package heat transfer limitations, not device power consumption)
1.5
W
DC ELECTRICAL CHARACTERISTICS
VDD = 4.5 V to 5.5 V; Tamb = 0 to +70 °C, unless otherwise specified.
VDD = 4.75 V to 5.25 V; Tamb = –40 to +85 °C, unless otherwise specified.
SYMBOL
PARAMETER
TEST CONDITIONS
LIMITS
MIN
TYP
MAX
UNIT
Supplies
IDD
Supply current operating
5.25 V, 30 MHz
110
mA
IID
Idle mode supply current
5.25 V, 30 MHz
40
mA
IPD
Power-down current
30
mA
IPDI
Power-down current (–40 °C to +85 °C)
150
mA
VRAM
RAM-keep-alive voltage
VIL
Input low voltage
VIH
Input high voltage, except XTAL1, RST
At 5.0 V
2.2
VIH1
Input high voltage to XTAL1, RST
At 5.0 V
0.8VDD
VIL1
Input low voltage to XATL1, RST
At 5.0 V
VOL
Output low voltage all ports, ALE, PSEN3
IOL = 3.2mA, VDD = 5.0 V
VOH1
Output high voltage all ports, ALE, PSEN1
IOH = –100mA, VDD = VDDmin
2.4
V
VOH2
Output high voltage, ports P0–3, ALE, PSEN2
IOH = 3.2mA, VDD = VDDmin
2.4
V
CIO
Input/Output pin capacitance
IIL
Logical 0 input current, P0–36
VIN = 0.45 V
ILI
Input leakage current, P0–35
ITL
Logical 1 to 0 transition current all ports4
RAM-keep-alive voltage
1.5
V
–0.5
0.22 VDD
V
V
V
0.12 VDD
0.5
V
15
pF
–75
mA
VIN = VIL or VIH
±10
mA
At 5.25 V
–650
mA
–25
NOTES:
1. Ports in Quasi bi-directional mode with weak pull-up (applies to ALE, PSEN only during RESET).
2. Ports in Push-Pull mode, both pull-up and pull-down assumed to be same strength
3. In all output modes
4. Port pins source a transition current when used in quasi-bidirectional mode and externally driven from 1 to 0. This current is highest when
VIN is approximately 2 V.
5. Measured with port in high impedance output mode.
6. Measured with port in quasi-bidirectional output mode.
7. Load capacitance for all outputs=80pF.
8. Under steady state (non-transient) conditions, IOL must be externally limited as follows:
15mA (*NOTE: This is 85 °C specification for VDD = 5 V.)
Maximum IOL per port pin:
Maximum IOL per 8-bit port:
26mA
Maximum total IOL for all output: 71mA
If IOL exceeds the test condition, VOL may exceed the related specification. Pins are not guaranteed to sink current greater than the listed
test conditions.
2002 Mar 13
32
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
AC ELECTRICAL CHARACTERISTICS (5 V)
VDD = 4.5 V to 5.5 V; Tamb = 0 to +70 °C for commercial; VDD = 4.75 V to 5.25 V, –40 °C to +85 °C for industrial.
VARIABLE CLOCK
SYMBOL
FIGURE
PARAMETER
MIN
MAX
0
30
UNIT
External Clock
fC
tC
Oscillator frequency
26
Clock period and CPU timing cycle
1/fC
MHz
ns
7
tCHCX
26
Clock high time
tC * 0.5
tCLCX
26
Clock low time
tC * 0.4 7
ns
tCLCH
26
Clock rise time
5
ns
tCHCL
26
Clock fall time
5
ns
tCRAR
25
Delay from clock rising edge to ALE rising edge
46
ns
tLHLL
20
ALE pulse width (programmable)
(V1 * tC) – 6
ns
tAVLL
20
Address valid to ALE de-asserted (set-up)
(V1 * tC) – 14
ns
tLLAX
20
Address hold after ALE de-asserted
(tC/2) – 10
ns
(V2 * tC) – 10
ns
ns
Address Cycle
5
Code Read Cycle
tPLPH
20
PSEN pulse width
tLLPL
20
ALE de-asserted to PSEN asserted
tAVIVA
20
Address valid to instruction valid, ALE cycle (access time)
(V3 * tC) – 36
ns
tAVIVB
21
Address valid to instruction valid, non-ALE cycle (access time)
(V4 * tC) – 29
ns
tPLIV
20
PSEN asserted to instruction valid (enable time)
(V2 * tC) – 29
ns
tPXIX
20
Instruction hold after PSEN de-asserted
tPXIZ
20
Bus 3-State after PSEN de-asserted (disable time)
tIXUA
20
Hold time of unlatched part of address after instruction latched
tRLRH
22
RD pulse width
tLLRL
22
ALE de-asserted to RD asserted
tAVDVA
22
Address valid to data input valid, ALE cycle (access time)
(V6 * tC) – 36
ns
tAVDVB
23
Address valid to data input valid, non-ALE cycle (access time)
(V5 * tC) – 29
ns
tRLDV
22
RD low to valid data in, enable time
(V7 * tC) – 29
ns
tRHDX
22
Data hold time after RD de-asserted
tRHDZ
22
Bus 3-State after RD de-asserted (disable time)
tDXUA
22
Hold time of unlatched part of address after data latched
tWLWH
24
tLLWL
24
tQVWX
(tC/2) – 7
ns
0
ns
tC – 8
ns
0
ns
(V7 * tC) – 10
ns
Data Read Cycle
(tC/2) – 7
ns
0
ns
tC – 8
ns
0
ns
WR pulse width
(V8 * tC) – 10
ns
ALE falling edge to WR asserted
(V12 * tC) – 10
ns
24
Data valid before WR asserted (data setup time)
(V13 * tC) – 22
ns
tWHQX
24
Data hold time after WR de-asserted (Note 6)
(V11 * tC) – 7
ns
tAVWL
24
Address valid to WR asserted (address setup time) (Note 5)
(V9 * tC) – 22
ns
tUAWH
24
Hold time of unlatched part of address after WR is de-asserted
(V11 * tC) – 7
ns
tWTH
25
WAIT stable after bus strobe (RD, WR, or PSEN) asserted
tWTL
25
WAIT hold after bus strobe (RD, WR, or PSEN) assertion
Data Write Cycle
Wait Input
(V10 * tC) – 30
(V10 * tC) – 5
NOTES:
1. Load capacitance for all outputs = 80pF.
2. Variables V1 through V13 reflect programmable bus timing, which is programmed via the Bus Timing registers (BTRH and BTRL).
Refer to the XA User Guide for details of the bus timing settings.
V1) This variable represents the programmed width of the ALE pulse as determined by the ALEW bit in the BTRL register.
V1 = 0.5 if the ALEW bit = 0, and 1.5 if the ALEW bit = 1.
2002 Mar 13
33
ns
ns
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
This variable represents the programmed width of the PSEN pulse as determined by the CR1 and CR0 bits or the CRA1, CRA0, and
ALEW bits in the BTRL register.
– For a bus cycle with no ALE, V2 = 1 if CR1/0 = 00, 2 if CR1/0 = 01, 3 if CR1/0 = 10, and 4 if CR1/0 = 11. Note that during burst
mode code fetches, PSEN does not exhibit transitions at the boundaries of bus cycles. V2 still applies for the purpose of
determining peripheral timing requirements.
– For a bus cycle with an ALE, V2 = the total bus cycle duration (2 if CRA1/0 = 00, 3 if CRA1/0 = 01, 4 if CRA1/0 = 10,
and 5 if CRA1/0 = 11) minus the number of clocks used by ALE (V1 + 0.5).
Example: If CRA1/0 = 10 and ALEW = 1, the V2 = 4 – (1.5 + 0.5) = 2.
V3) This variable represents the programmed length of an entire code read cycle with ALE. This time is determined by the CRA1 and
CRA0 bits in the BTRL register. V3 = the total bus cycle duration (2 if CRA1/0 = 00, 3 if CRA1/0 = 01, 4 if CRA1/0 = 10,
and 5 if CRA1/0 = 11).
V4) This variable represents the programmed length of an entire code read cycle with no ALE. This time is determined by the CR1 and
CR0 bits in the BTRL register. V4 = 1 if CR1/0 = 00, 2 if CR1/0 = 01, 3 if CR1/0 = 10, and 4 if CR1/0 = 11.
V5) This variable represents the programmed length of an entire data read cycle with no ALE. this time is determined by the DR1 and
DR0 bits in the BTRH register. V5 = 1 if DR1/0 = 00, 2 if DR1/0 = 01, 3 if DR1/0 = 10, and 4 if DR1/0 = 11.
V6) This variable represents the programmed length of an entire data read cycle with ALE. The time is determined by the DRA1 and
DRA0 bits in the BTRH register. V6 = the total bus cycle duration (2 if DRA1/0 = 00, 3 if DRA1/0 = 01, 4 if DRA1/0 = 10,
and 5 if DRA1/0 = 11).
V7) This variable represents the programmed width of the RD pulse as determined by the DR1 and DR0 bits or the DRA1, DRA0 in the
BTRH register, and the ALEW bit in the BTRL register. Note that during a 16-bit operation on an 8-bit external bus, RD remains low
and does not exhibit a transition between the first and second byte bus cycles. V7 still applies for the purpose of determining
peripheral timing requirements. The timing for the first byte is for a bus cycle with ALE, the timing for the second byte is for a bus
cycle with no ALE.
– For a bus cycle with no ALE, V7 = 1 if DR1/0 = 00, 2 if DR1/0 = 01, 3 if DR1/0 = 10, and 4 if DR1/0 = 11.
– For a bus cycle with an ALE, V7 = the total bus cycle duration (2 if DRA1/0 = 00, 3 if DRA1/0 = 01, 4 if DRA1/0 = 10,
and 5 if DRA1/0 = 11) minus the number of clocks used by ALE (V1 + 0.5).
Example: If DRA1/0 = 00 and ALEW = 0, then V7 = 2 – (0.5 + 0.5) = 1.
V8) This variable represents the programmed width of the WRL and/or WRH pulse as determined by the WM1 bit in the BTRL register.
V8 1 if WM1 = 0, and 2 if WM1 = 1.
V9) This variable represents the programmed address setup time for a write as determined by the data write cycle duration (defined by
DW1 and DW0 or the DWA1 and DWA0 bits in the BTRH register), the WM0 bit in the BTRL register, and the value of V8.
– For a bus cycle with an ALE, V9 = the total bus write cycle duration (2 if DWA1/0 = 00, 3 if DWA1/0 = 01, 4 if DWA1/0 = 10, and 5
if DWA1/0 = 11) minus the number of clocks used by the WRL and/or WRH pulse (V8), minus the number of clocks used by data
hold time (0 if WM0 = 0 and 1 if WM0 = 1).
Example: If DWA1/0 = 10, WM0 = 1, and WM1 = 1, then V9 = 4 – 1 – 2 = 1.
– For a bus cycle with no ALE, V9 = the total bus cycle duration (2 if DW1/0 = 00, 3 if DW1/0 = 01, 4 if DW1/0 = 10, and
5 if DW1/0 = 11) minus the number of clocks used by the WRL and/or WRH pulse (V8), minus the number of clocks used by data
hold time (0 if WM0 = 0 and 1 if WM0 = 1).
Example: If DW1/0 = 11, WM0 = 1, and WM1 = 0, then V9 = 5 – 1 – 1 = 3.
V10) This variable represents the length of a bus strobe for calculation of WAIT setup and hold times. The strobe may be RD (for data read
cycles), WRL and/or WRH (for data write cycles), or PSEN (for code read cycles), depending on the type of bus cycle being widened
by WAIT. V10 = V2 for WAIT associated with a code read cycle using PSEN. V10 = V8 for a data write cycle using WRL and/or WRH.
V10 = V7–1 for a data read cycle using RD. This means that a single clock data read cycle cannot be stretched using WAIT.
If WAIT is used to vary the duration of data read cycles, the RD strobe width must be set to be at least two clocks in duration.
Also see Note 4.
V11) This variable represents the programmed write hold time as determined by the WM0 bit in the BTRL register.
V11 = 0 if the WM0 bit = 0, and 1 if the WM0 bit = 1.
V12) This variable represents the programmed period between the end of the ALE pulse and the beginning of the WRL and/or WRH pulse
as determined by the data write cycle duration (defined by the DWA1 and DWA0 bits in the BTRH register), the WM0 bit in the BTRL
register, and the values of V1 and V8. V12 = the total bus cycle duration (2 if DWA1/0 = 00, 3 if DWA1/0 = 01, 4 if DWA1/0 = 10, and
5 if DWA1/0 = 11) minus the number of clocks used by the WRL and/or WRH pulse (V8), minus the number of clocks used by data
hold time (0 if WM0 = 0 and 1 if WM0 = 1), minus the width of the ALE pulse (V1).
Example: If DWA1/0 = 11, WM0 = 1, WM1 = 0, and ALEW = 1, then V12 = 5 – 1 – 1 – 1.5 = 1.5.
V13) This variable represents the programmed data setup time for a write as determined by the data write cycle duration (defined by DW1
and DW0 or the DWA1 and DWA0 bits in the BTRH register), the WM0 bit in the BTRL register, and the values of V1 and V8.
– For a bus cycle with an ALE, V13 = the total bus cycle duration (2 if DWA1/0 = 00, 3 if DWA1/0 = 01, 4 if DWA1/0 = 10, and
5 if DWA1/0 = 11) minus the number of clocks used by the WRL and/or WRH pulse (V8), minus the number of clocks used by
data hold time (0 if WM0 = 0 and 1 if WM0 = 1), minus the number of clocks used by ALE (V1 + 0.5).
Example: If DWA1/0 = 11, WM0 = 1, WM1 = 1, and ALEW = 0, then V13 = 5 – 1 – 2 – 1 = 1.
– For a bus cycle with no ALE, V13 = the total bus cycle duration (2 if DW1/0 = 00, 3 if DW1/0 = 01, 4 if DW1/0 = 10, and
5 if DW1/0 = 11) minus the number of clocks used by the WRL and/or WRH pulse (V8), minus the number of clocks used by
data hold time (0 if WM0 = 0 and 1 if WM0 = 1).
Example: If DW1/0 = 01, WM0 = 1, and WM1 = 0, then V13 = 3 – 1 – 1 = 1.
3. Not all combinations of bus timing configuration values result in valid bus cycles. Please refer to the XA User Guide section on the External
Bus for details.
4. When code is being fetched for execution on the external bus, a burst mode fetch is used that does not have PSEN edges in every fetch
cycle. Thus, if WAIT is used to delay code fetch cycles, a change in the low order address lines must be detected to locate the beginning of
a cycle. This would be A3–A0 for an 8-bit bus, and A3–A1 for a 16-bit bus. Also, a 16-bit data read operation conducted on a 8-bit wide bus
similarly does not include two separate RD strobes. So, a rising edge on the low order address line (A0) must be used to trigger a WAIT in
the second half of such a cycle.
V2)
2002 Mar 13
34
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
5. This parameter is provided for peripherals that have the data clocked in on the falling edge of the WR strobe. This is not usually the case,
and in most applications this parameter is not used.
6. Please note that the XA-G39 requires that extended data bus hold time (WM0 = 1) to be used with external bus write cycles.
7. Applies only to an external clock source, not when a crystal or ceramic resonator is connected to the XTAL1 and XTAL2 pins.
tLHLL
ALE
tAVLL
tLLPL
tPLPH
tPLIV
PSEN
tLLAX
tPXIZ
tPXIX
MULTIPLEXED
ADDRESS AND DATA
A4–A11 or A4–A19
INSTR IN *
tIXUA
tAVIVA
UNMULTIPLEXED
ADDRESS
*
A0 or A1–A3, A12–19
INSTR IN is either D0–D7 or D0–D15, depending on the bus width (8 or 16 bits).
SU01073
Figure 20. External Program Memory Read Cycle (ALE Cycle)
ALE
PSEN
MULTIPLEXED
ADDRESS AND DATA
A4–A11 or A4–A19
INSTR IN *
tAVIVB
UNMULTIPLEXED
ADDRESS
*
A0 or A1–A3, A12–19
A0 or A1–A3, A12–19
INSTR IN is either D0–D7 or D0–D15, depending on the bus width (8 or 16 bits).
Figure 21. External Program Memory Read Cycle (Non-ALE Cycle)
2002 Mar 13
35
SU00707
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
ALE
tLLRL
RD
tAVLL
tRLRH
tLLAX
tRHDZ
tRLDV
tRHDX
MULTIPLEXED
ADDRESS
AND DATA
A4–A11 or A4–A19
DATA IN
*
tDXUA
tAVDVA
UNMULTIPLEXED
ADDRESS
*
A0 or A1–A3, A12–A19
DATA IN is either D0–D7 or D0–D15, depending on the bus width (8 or 16 bits).
SU00947
Figure 22. External Data Memory Read Cycle (ALE Cycle)
ALE
RD
MULTIPLEXED
ADDRESS
AND DATA
D0–D7
A4–A11
DATA IN
*
tAVDVB
UNMULTIPLEXED
ADDRESS
A0–A3, A12–A19
A0–A3, A12–A19
SU00708A
Figure 23. External Data Memory Read Cycle (Non-ALE Cycle)
2002 Mar 13
36
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
ALE
tWLWH
tLLWL
WRL or WRH
tLLAX
tAVLL
MULTIPLEXED
ADDRESS
AND DATA
tQVWX
tWHQX
DATA OUT *
A4–A11 or A4–A15
tAVWL
tUAWH
UNMULTIPLEXED
ADDRESS
*
A0 or A1–A3, A12–A19
DATA OUT is either D0–D7 or D0–D15, depending on the bus width (8 or 16 bits).
SU00584C
Figure 24. External Data Memory Write Cycle
XTAL1
tCRAR
ALE
ADDRESS BUS
WAIT
BUS STROBE
(WRL, WRH,
RD, OR PSEN)
tWTH
(The dashed line shows the strobe without WAIT.)
tWTL
SU00709A
Figure 25. WAIT Signal Timing
2002 Mar 13
37
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
VDD–0.5
XA-G39
0.7VDD
0.2VDD–0.1
0.45V
tCHCL
tCHCX
tCLCH
tCLCX
tC
SU00842
Figure 26. External Clock Drive
VDD–0.5
0.2VDD+0.9
0.2VDD–0.1
0.45V
NOTE:
AC inputs during testing are driven at VDD –0.5 for a logic ‘1’ and 0.45V for a logic ‘0’.
Timing measurements are made at the 50% point of transitions.
SU00703A
Figure 27. AC Testing Input/Output
VLOAD+0.1V
VOH–0.1V
TIMING
REFERENCE
POINTS
VLOAD
VLOAD–0.1V
VOL+0.1V
NOTE:
For timing purposes, a port is no longer floating when a 100mV change from load voltage occurs,
and begins to float when a 100mV change from the loaded VOH/VOL level occurs. IOH/IOL ≥ ±20mA.
SU00011
Figure 28. Float Waveform
VDD
VDD
VDD
VDD
RST
VDD
RST
EA
EA
(NC)
XTAL2
(NC)
XTAL2
CLOCK SIGNAL
XTAL1
CLOCK SIGNAL
XTAL1
VSS
VSS
SU00591B
SU00590B
Figure 29. IDD Test Condition, Active Mode
All other pins are disconnected
2002 Mar 13
Figure 30. IDD Test Condition, Idle Mode
All other pins are disconnected
38
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
120
MAX. IDD (ACTIVE)
100
80
60
CURRENT (mA)
40
MAX. IDD (IDLE)
20
0
0
5
15
10
25
20
30
FREQUENCY (MHz)
SU00844
Figure 31. IDD vs. Frequency
Valid only within frequency specification of the device under test.
VDD–0.5
0.7VDD
0.2VDD–0.1
0.45V
tCHCL
tCHCX
tCLCH
tCLCX
tCL
SU00608A
Figure 32. Clock Signal Waveform for IDD Tests in Active and Idle Modes
tCLCH = tCHCL = 5ns
VDD
VDD
VDD
RST
EA
(NC)
XTAL2
XTAL1
VSS
SU00585A
Figure 33. IDD Test Condition, Power Down Mode
All other pins are disconnected. VDD=2 V to 5.5 V
2002 Mar 13
39
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
PLCC44: plastic leaded chip carrier; 44 leads
2002 Mar 13
XA-G39
SOT187-2
40
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
REVISION HISTORY
Date
CPCN
Description
2002 Mar 13
9397 750 08927
Initial release
2002 Mar 13
41
XA-G39
Philips Semiconductors
Preliminary data
XA 16-bit microcontroller family
32K Flash/1K RAM, watchdog, 2 UARTs
XA-G39
Data sheet status
Data sheet status [1]
Product
status [2]
Definitions
Objective data
Development
This data sheet contains data from the objective specification for product development.
Philips Semiconductors reserves the right to change the specification in any manner without notice.
Preliminary data
Qualification
This data sheet contains data from the preliminary specification. Supplementary data will be
published at a later date. Philips Semiconductors reserves the right to change the specification
without notice, in order to improve the design and supply the best possible product.
Product data
Production
This data sheet contains data from the product specification. Philips Semiconductors reserves the
right to make changes at any time in order to improve the design, manufacturing and supply.
Changes will be communicated according to the Customer Product/Process Change Notification
(CPCN) procedure SNW-SQ-650A.
[1] Please consult the most recently issued data sheet before initiating or completing a design.
[2] The product status of the device(s) described in this data sheet may have changed since this data sheet was published. The latest information is available on the Internet at URL
http://www.semiconductors.philips.com.
Definitions
Short-form specification — The data in a short-form specification is extracted from a full data sheet with the same type number and title. For
detailed information see the relevant data sheet or data handbook.
Limiting values definition — Limiting values given are in accordance with the Absolute Maximum Rating System (IEC 60134). Stress above one
or more of the limiting values may cause permanent damage to the device. These are stress ratings only and operation of the device at these or
at any other conditions above those given in the Characteristics sections of the specification is not implied. Exposure to limiting values for extended
periods may affect device reliability.
Application information — Applications that are described herein for any of these products are for illustrative purposes only. Philips
Semiconductors make no representation or warranty that such applications will be suitable for the specified use without further testing or
modification.
Disclaimers
Life support — These products are not designed for use in life support appliances, devices or systems where malfunction of these products can
reasonably be expected to result in personal injury. Philips Semiconductors customers using or selling these products for use in such applications
do so at their own risk and agree to fully indemnify Philips Semiconductors for any damages resulting from such application.
Right to make changes — Philips Semiconductors reserves the right to make changes, without notice, in the products, including circuits, standard
cells, and/or software, described or contained herein in order to improve design and/or performance. Philips Semiconductors assumes no
responsibility or liability for the use of any of these products, conveys no license or title under any patent, copyright, or mask work right to these
products, and makes no representations or warranties that these products are free from patent, copyright, or mask work right infringement, unless
otherwise specified.
 Koninklijke Philips Electronics N.V. 2002
All rights reserved. Printed in U.S.A.
Contact information
For additional information please visit
http://www.semiconductors.philips.com.
Fax: +31 40 27 24825
Date of release: 03-02
For sales offices addresses send e-mail to:
[email protected].
Document order number:
2002 Mar 13
42
9397 750 08927