TI MSP430P337AHFD Mixed signal microcontroller Datasheet

MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
D
D
D
D
D
D
D
D
D
D
Low Supply Voltage Range 2.5 V – 5.5 V
Low Operation Current,
400 mA at 1 MHz, 3 V
Ultra-Low Power Consumption
Standby Mode: 2 µA
RAM Retention Off Mode: 0.1 µA
Five Power-Saving Modes
Wake Up From Standby Mode in 6 µs
16-Bit RISC Architecture, 300 ns Instruction
Cycle Time
Single Common 32 kHz Crystal, Internal
System Clock up to 3.8 MHz
Integrated LCD Driver for up to 120
Segments
Integrated Hardware Multiplier Performs
Signed, Unsigned, and MAC Operations for
Operands Up to 16 X 16 Bits
Serial Communication Interface (USART),
Select Asynchronous UART or
Synchronous SPI by Software
D
D
D
D
D
D
D
Slope A/D Converter Using External
Components
16-Bit Timer With Five Capture/Compare
Registers
Serial On-Board Programming
Programmable Code Protection by Security
Fuse
Family Members Include:
MSP430C336 – 24 KB ROM, 1 KB RAM
MSP430C337 – 32 KB ROM, 1 KB RAM
MSP430P337A – 32 KB OTP, 1 KB RAM
EPROM Version Available for Prototyping:
PMS430E337A
Available in the following packages:
100 Pin Quad Flat-Pack (QFP),
100 Pin Ceramic Quad Flat-Pack (CFP)
(EPROM Version)
description
The Texas Instruments MSP430 is an ultra-low power mixed signal microcontroller family consisting of several
devices which features different sets of modules targeted to various applications. The controller is designed to
be battery operated for an extended application lifetime. With the 16-bit RISC architecture, 16 integrated
registers on the CPU, and a constant generator, the MSP430 achieves maximum code efficiency. The
digital-controlled oscillator, together with the frequency lock loop (FLL), provides a wake up from a low-power
mode to an active mode in less than 6 ms. The MSP430x33x series micro-controllers have built in hardware
multiplication and communication capability using asynchronous (UART) and synchronous protocols.
Typical applications of the MSP430 family include electronic gas, water, and electric meters and other sensor
systems that capture analog signals, converts them to digital values, processes, displays, or transmits them to
a host system.
Please be aware that an important notice concerning availability, standard warranty, and use in critical applications of
Texas Instruments semiconductor products and disclaimers thereto appears at the end of this data sheet.
Copyright  1999, Texas Instruments Incorporated
PRODUCTION DATA information is current as of publication date.
Products conform to specifications per the terms of Texas Instruments
standard warranty. Production processing does not necessarily include
testing of all parameters.
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1
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
AVAILABLE OPTIONS
PACKAGED DEVICES
PLASTIC
QFP
(PJM)
CERAMIC
QFP
(HFD)
– 40°C to 85°C
MSP430C336IPJM
MSP430C337IPJM
MSP430P337AIPJM
—
25°C
—
PMS430E337AHFD
TA
1
2
3
4
5
6
7
8
9
10
11
12
13
14
15
16
17
18
19
20
21
22
23
24
25
26
27
28
29
30
80
79
78
77
76
75
74
73
72
71
70
69
68
67
66
65
64
63
62
61
60
59
58
57
56
55
54
53
52
51
P2.3
P2.4
P2.5
P2.6
P2.7
P3.0
P3.1
P3.2/TACLK
P3.3/TA0
P3.4/TA1
P3.5/TA2
P3.6/TA3
P3.7/TA4
P4.0
P4.1
P4.2/STE
P4.3/SIMO
P4.4/SOMI
P4.5/UCLK
P4.6/UTXD
31
32
33
34
35
36
37
38
39
40
41
42
43
44
45
46
47
48
49
50
VCC1
CIN
TP0.0
TP0.1
TP0.2
TP0.3
TP0.4
TP0.5
P0.0
P0.1/RXD
P0.2/TXD
P0.3
P0.4
P0.5
P0.6
P0.7
P1.0
P1.1
P1.2
P1.3
P1.4
P1.5
P1.6
P1.7
P2.0
P2.1
P2.2
VSS2
VCC2
NC
100
99
98
97
96
95
94
93
92
91
90
89
88
87
86
85
84
83
82
81
VSS1
Xin
Xout/TCLK
XBUF
RST/NMI
TCK
TMS
TDI/VPP
TDO/TDI
R33
R23
R13
R03
S29/O29/CMPI
S28/O28
S27/O27
S26/O26
S25/O25
S24/O24
S23/O23
PJM or HFD PACKAGE
(TOP VIEW)
NC – No internal connection
2
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NC
S22/O22
S21/O21
S20/O20
S19/O19
S18/O18
S17/O17
S16/O16
S15/O15
S14/O14
S13/O13
S12/O12
S11/O11
S10/O10
S9/O9
S8/O8
S7/07
S6/O6
S5/O5
S4/O4
S3/O3
S2/O2
S1
S0
COM0
COM1
COM2
COM3
VSS3
P4.7/URXD
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TCK
TMS
TDO/TDI
TDI/VPP
Test
JTAG
CPU
Incl. 16 Reg.
ACLK
Oscillator
FLL
System Clock
Multiplier
MPY
MPYS
MAC
16x16 Bit
8x8 Bit
MDB, 16 Bit
MAB, 16 Bit
MCLK
XBUF
Xout
XIN
VCC2
• DALLAS, TEXAS 75265
15/16 Bit
Watchdog
timer
C: ROM
P: OTP
E: EPROM
24/32 kB ROM
32 kB OPT or
EPROM
VCC1
VSS3
TACLK
TA0–4
16 Bit
PWM
TimerA
UTXD
URXD
UCLK
STE
SIMO
SOMI
UART or
SPI Function
P4.7
TXD
RXD
8 Bit
Timer/Counter
1x8 Digital
I/O’s
I/O Port
P4.0
USART
USART
MDB, 8 Bit
MCB
MAB, 4 Bit
Reset
SRAM
Power-on-
RST/NMI
RAM
Bus
Conv
VSS2
1024B
VSS1
8
8
Timer/Port
TP0.0–0.5
CIN
6
A/D Conv.
Timer, O/P
Applications
TimerA
2 Int. Vectors
2x8 I/O’s All
Interr. Cap.
I/O Port
P1.x
P2.x
CMPI
f LCD
Basic
Timer1
1x8 Digital
I/O’s
RXD,
TXD
P3.7
I/O Port
P3.0
P0.7
R03 R23
R13 R33
1, 2, 3, 4 MUX
120 Segments
LCD
3 Int. Vectors
8 I/O’s, All With
Interr. Cap.
I/O Port
P0.0
Com0–3
S0–28/O2–28
S29/O29/CMPI
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
functional block diagram
3
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
Terminal Functions
TERMINAL
NAME
CIN
COM0–3
NO.
2
I/O
DESCRIPTION
I
Input port. CIN is used as an enable for counter TPCNT1 – (Timer/Port).
56–53
O
Common outputs. COM0-3 are used for LCD backplanes – LCD
P0.0
9
I/O
General-purpose digital I/O
P0.1/RXD
10
I/O
General-purpose digital I/O, receive digital Input port – 8-bit Timer/Counter
P0.2/TXD
11
I/O
General-purpose digital I/O, transmit data output port – 8-bit Timer/Counter
P0.3–P0.7
12–16
I/O
Five general-purpose digital I/Os, bit 3-7
P1.0–P1.7
17–24
I/O
Eight general-purpose digital I/Os, bit 0-7
P2.0–P2.7
25–27,
31–35
I/O
Eight general-purpose digital I/Os, bit 0-7
P3.0, P3.1
36,37
I/O
Two general-purpose digital I/Os, bit 0 and bit 1
P3.2/TACLK
38
I/O
General-purpose digital I/O, clock input – Timer_A
P3.3/TA0
39
I/O
General-purpose digital I/O, capture I/O, or PWM output port – Timer_A CCR0
P3.4/TA1
40
I/O
General-purpose digital I/O, capture I/O, or PWM output port – Timer_A CCR1
P3.5/TA2
41
I/O
General-purpose digital I/O, capture I/O, or PWM output port – Timer_A CCR2
P3.6/TA3
42
I/O
General-purpose digital I/O, capture I/O, or PWM output port – Timer_A CCR3
P3.7/TA4
43
I/O
General-purpose digital I/O, capture I/O, or PWM output port – Timer_A CCR4
P4.0
44
I/O
General-purpose digital I/O, bit 0
P4.1
45
I/O
General-purpose digital I/O, bit 1
P4.2/STE
46
I/O
General-purpose digital I/O, slave transmit enable – USART/SPI mode
P4.3/SIMO
47
I/O
General-purpose digital I/O, slave in/master out – USART/SPI mode
P4.4/SOMI
48
I/O
General-purpose digital I/O, master in/slave out – USART/SPI mode
P4.5/UCLK
49
I/O
General-purpose digital I/O, external clock input – USART
P4.6/UTXD
50
I/O
General-purpose digital I/O, transmit data out – USART/UART mode
P4.7/URXD
51
I/O
General-purpose digital I/O, receive data in – USART/UART mode
R03
88
I
Input port of fourth positive (lowest) analog LCD level (V5) – LCD
R13
89
I
Input port of third most positive analog LCD level (V3 of V4) – LCD
R23
90
I
Input port of second most positive analog LCD level (V2) – LCD
R33
91
O
Output of most positive analog LCD level (V1) – LCD
RST/NMI
96
I
Reset input or non-maskable interrupt input port
S0
57
O
Segment line S0 – LCD
S1
58
O
Segment line S1 – LCD
S2/O2–S5/O5
59–62
O
Segment lines S2 to S5 or digital output ports, O2-O5, group 1 – LCD
S6/O6–S9/O9
63–66
O
Segment lines S6 to S9 or digital output ports O6-O9, group 2 – LCD
S10/O10–S13/O13
67–70
O
Segment lines S10 to S13 or digital output ports O10-O13, group 3 – LCD
S14/O14–S17/O17
71–74
O
Segment lines S14 to S17 or digital output ports O14-O17, group 4 – LCD
S18/O18–S21/O21
75–78
O
Segment lines S18 to S21 or digital output ports O18-O21, group 5 – LCD
S22/O22–S25/O25
79, 81–83
O
Segment line S22 to S25 or digital output ports O22-O25, group 6 – LCD
84–87
O
Segment line S26 to S29 or digital output ports O26-O29, group 7 – LCD. Segment line S29
can be used as comparator input port CMPI – Timer/Port
TCK
95
I
Test clock. TCK is the clock input port for device programming and test
TDI/VPP
93
I
Test data input. TDI/VPP is used as a data input port or input for programming voltage
S26/O26–S29/O29/CMPI
4
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
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Terminal Functions
TERMINAL
NAME
NO.
I/O
DESCRIPTION
TMS
94
I
Test mode select. TMS is used as an input port for device programming and test
TDO/TDI
92
I/O
Test data output port. TDO/TDI data output or programming data input terminal
TP0.0
3
O
General-purpose 3-state digital output port, bit 0 – Timer/Port
TP0.1
4
O
General-purpose 3-state digital output port, bit 1 – Timer/Port
TP0.2
5
O
General-purpose 3-state digital output port, bit 2 – Timer/Port
TP0.3
6
O
General-purpose 3-state digital output port, bit 3 – Timer/Port
TP0.4
7
O
General-purpose 3-state digital output port, bit 4 – Timer/Port
TP0.5
8
I/O
General-purpose 3-state digital input/output port, bit 5 – Timer/Port
VCC1
1
Positive supply voltage
VCC2
29
Positive supply voltage
VSS1
100
Ground reference
VSS2
28
Ground reference
VSS3
52
Ground reference
XBUF
97
O
System clock (MCLK) or crystal clock (ACLK) output
Xin
99
I
Input port for crystal oscillator
Xout/TCLK
98
I/O
Output terminal of crystal oscillator or test clock input
short-form description
processing unit
The processing unit is based on a consistent and orthogonal designed CPU and instruction set. This design
structure results in a RISC-like architecture, highly transparent to the application development and is
distinguished due to ease of programming. All operations, other than program-flow instructions consequently
are performed as register operations in conjunction with seven addressing modes for source and four modes
for destination operand.
CPU registers
Sixteen registers are located inside the CPU,
providing reduced instruction execution time. This
reduces a register-register operation execution
time to one cycle of the processor frequency.
PC/R0
Stack Pointer
SP/R1
Status Register
Four of the registers are reserved for special use
as a program counter, a stack pointer, a status
register and a constant generator. The remaining
registers are available as general purpose
registers.
Constant Generator
Peripherals are connected to the CPU using a
data address and control bus and can be handled
easily with all instructions for memory manipulation.
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SR/CG1/R2
CG2/R3
General Purpose Register
R4
General Purpose Register
R5
General Purpose Register
R14
General Purpose Register
R15
5
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
instruction set
The instruction set for this register-register architecture provides a powerful and easy-to-use assembly
language. The instruction set consists of 51 instructions, with three formats and seven addressing modes.
Table 1 provides a summation and example of the three types of instruction formats; the addressing modes are
listed in Table 2.
Table 1. Instruction Word Formats
Dual operands, source-destination
e.g. ADD R4,R5
R4 + R5 → R5
Single operands, destination only
e.g. CALL R8
PC → (TOS), R8→ PC
Relative jump, un–/conditional
e.g. JNE
Jump-on equal bit = 0
Instructions that can operate on both word and byte data are differentiated by the suffix .B when a byte operation
is required.
Examples:
Instructions for word operation:
Instructions for byte operation:
MOV
EDE,TONI
MOV.B
EDE,TONI
ADD
#235h,&MEM
ADD.B
#35h,&MEM
PUSH
R5
PUSH.B
R5
SWPB
R5
–––
Table 2. Address Mode Descriptions
S
D
Register
ADDRESS MODE
√
√
MOV Rs,Rd
SYNTAX
MOV R10,R11
EXAMPLE
R10 → R11
OPERATION
Indexed
√
√
MOV X(Rn),Y(Rm)
MOV 2(R5),6(R6)
M(2+R5) → M(6+R6)
Symbolic (PC relative)
√
√
MOV EDE,TONI
Absolute
√
√
MOV &MEM,&TCDAT
Indirect
√
MOV @Rn,Y(Rm)
MOV @R10,Tab(R6)
M(R10) → M(Tab+R6)
Indirect autoincrement
√
MOV @Rn+,Rm
MOV @R10+,R11
M(R10) → R11
R10 + 2→ R10
Immediate
√
MOV #X,TONI
MOV #45,TONI
#45 → M(TONI)
M(EDE) → M(TONI)
M(MEM) → M(TCDAT)
NOTE 1: S = source, D = destination.
Computed branches (BR) and subroutine calls (CALL) instructions use the same addressing modes as the other
instructions. These addressing modes provide indirect addressing, ideally suited for computed branches and
calls. The full use of this programming capability permits a program structure different from conventional 8- and
16-bit controllers. For example, numerous routines can easily be designed to deal with pointers and stacks
instead of using flag type programs for flow control.
6
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
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operation modes and interrupts
The MSP430 operating modes support various advanced requirements for ultra-low power and ultra-low energy
consumption. This is achieved by the intelligent management of the operations during the different module
operation modes and CPU states. The requirements are fully supported during interrupt event handling. An
interrupt event awakens the system from each of the various operating modes and returns with the RETI
instruction to the mode that was selected before the interrupt event. The clocks used are ACLK and MCLK.
ACLK is the crystal frequency and MCLK is a multiple of ACLK and is used as the system clock.
The following five operating modes are supported:
D
D
D
D
D
D
Active mode (AM). The CPU is enabled with different combinations of active peripheral modules.
Low power mode 0 (LPM0). The CPU is disabled, peripheral operation continues, ACLK and MCLK signals
are active, and loop control for MCLK is active.
Low power mode 1 (LPM1). The CPU is disabled, peripheral operation continues, ACLK and MCLK signals
are active, and loop control for MCLK is inactive.
Low power mode 2 (LMP2). The CPU is disabled, peripheral operation continues, ACLK signal is active,
and MCLK and loop control for MCLK are inactive.
Low power mode 3 (LMP3). The CPU is disabled, peripheral operation continues, ACLK signal is active,
MCLK and loop control for MCLK are inactive, and the dc generator for the digital controlled oscillator (DCO)
( MCLK generator) is switched off.
³
Low power mode 4 (LMP4). The CPU is disabled, peripheral operation continues, ACLK signal is inactive
(crystal oscillator stopped), MCLK and loop control for MCLK are inactive, and the dc generator for the DCO
is switched off.
The special function registers (SFR) include module-enable bits that stop or enable the operation of the specific
peripheral module. All registers of the peripherals may be accessed if the operational function is stopped or
enabled. However, some peripheral current-saving functions are accessed through the state of local register
bits. An example is the enable/disable of the analog voltage generator in the LCD peripheral, which is turned
on or off using one register bit.
The most general bits that influence current consumption and support fast turn-on from low power operating
modes are located in the status register (SR). Four of these bits control the CPU and the system clock generator:
SCG1, SCG0, OscOff, and CPUOff.
15
Reserved For Future
Enhancements
9
8
V
7
SCG1
0
SCG0
OscOff
CPUOff
GIE
N
Z
C
rw-0
interrupts
Software determines the activation of interrupts through the monitoring of hardware set interrupt flag status bits,
the control of specific interrupt enable bits in SRs, the establishment of interrupt vectors, and the programming
of interrupt handlers. The interrupt vectors and the power-up starting address are located in ROM address
locations 0FFFFh through 0FFE0h. Each vector contains the 16-bit address of the appropriate interrupt handler
instruction sequence. Table 3 provides a summation of interrupt functions and addresses.
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
Table 3. Interrupt Functions and Addresses
INTERRUPT SOURCE
INTERRUPT FLAG
Power-up, external reset, Watchdog
WDTIFG
NMI,
Oscillator fault
NMIIFG (see Notes 2 and 4)
OFIFG (see Notes 2 and 5)
Dedicated I/O P0.0
Dedicated I/O P0.1 or 8-bit Timer/Counter
SYSTEM INTERRUPT
WORD ADDRESS
PRIORITY
Reset
0FFFEh
15, highest
Non-maskable
(Non)-maskable
0FFFCh
14
P0IFG.0
Mmaskable
0FFFAh
13
P0IFG.1
Maskable
0FFF8h
12
Maskable
0FFF6h
11
Watchdog Timer
WDTIFG
Maskable
0FFF4h
10
Timer_A
CCIFG0 (see Note 3)
Maskable
0FFF2h
9
Timer_A
TAIFG (see Note 3)
Maskable
0FFF0h
8
UART receive
URXIFG
Maskable
0FFEEh
7
UART transmit
UTXIFG
Maskable
0FFECh
6
0FFEAh
5
Timer/Port
RC1FG,, RC2FG,, EN1FG
(see Note 3)
Maskable
0FFE8h
4
I/O port P2
P2IFG.07 (see Note 2)
Maskable
0FFE6h
3
I/O port P1
P1IFG.07 (see Note 2)
Maskable
0FFE4h
2
Basic Timer1
BTIFG
Maskable
0FFE2h
1
I/O port P0.2 – P0.7
P0IFG.27 (see Note 2)
Maskable
0FFE0h
0, lowest
NOTES: 2.
3.
4.
5.
Multiple source flags
Interrupt flags are located in the individual module registers.
Non-maskable : neither the individual or the general interrupt enable bit will disable an interrupt event.
(Non)-maskable: the individual interrupt enable bit can disable an interrupt event, but the general interrupt enable bit cannot.
special function registers
Most interrupt and module enable bits are collected into the lowest address space. Special function register bits
that are not allocated to a functional purpose are not physically present in the device. Simple software access
is provided with this arrangement.
interrupt enable 1 and 2
7
Address
6
5
4
0h
3
2
1
P0IE.1
P0IE.0
OFIE
rw-0
WDTIE:
OFIE:
P0IE.0:
P0IE.1:
Watchdog Timer interrupt enable signal
Oscillator fault interrupt enable signal
Dedicated I/O P0.0 interrupt enable signal
P0.1 or 8-bit Timer/Counter, RXD interrupt enable signal
Address
7
01h
6
5
4
3
BTIE
TPIE
rw-0
URXIE:
UTXIE:
TPIE:
BTIE:
8
rw-0
rw-0
USART receive interrupt enable signal
USART transmit interrupt enable signal
Timer/Port interrupt enable signal
Basic Timer1 interrupt enable signal
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rw-0
2
0
WDTIE
rw-0
1
UTXIE
rw-0
0
URXIE
rw-0
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
interrupt flag registers 1 and 2
7
Address
6
5
02h
4
3
2
1
NMIIFG
P0IFG.1
P0IFG.0
OFIFG
rw-0
WDTIFG:
rw-0
rw-0
rw-1
OFIFG:
P0IFG.0:
P0IFG.1:
NMIIFG:
Set on overflow or security key violation
or
Reset on VCC1 power-on or reset condition at RST/NMI-pin
Flag set on oscillator fault
Dedicated I/O P0.0
P0.1 or 8-bit Timer/Counter, RXD
Signal at RST/NMI-pin
Address
7
03h
6
5
4
3
2
BTIFG
URXIFG:
UTXIFG:
BTIFG:
WDTIFG
rw-0
1
UTXIFG
rw
0
rw-1
0
URXIFG
rw-0
USART receive flag
USART transmit flag
Basic Timer1 flag
module enable registers 1 and 2
Address
7
6
5
4
3
2
1
0
7
6
5
4
3
2
1
0
04h
Address
05h
UTXE
rw-0
UTXE:
URXE:
Legend
URXE
rw-0
USART transmit enable
USART receive enable
rw:
rw-0:
Bit can be read and written
Bit can be read and written. It is reset by PUC
SFR bit not present in device
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
ROM memory organization
MSP430C337
MSP430C336
FFFFh
FFE0h
FFDFh
Int. Vector
FFFFh
FFE0h
FFDFh
24 kB ROM
Int. Vector
MSP430P337A
PMS430E337A
FFFFh
FFE0h
FFDFh
32 kB ROM
Int. Vector
32 kB OTP
or
EPROM
A000h
8000h
05FFh
0200h
01FFh
0100h
00FFh
0010h
000Fh
0000h
1024B RAM
16b Per.
8b Per.
SFR
05FFh
0200h
01FFh
0100h
00FFh
0010h
000Fh
0000h
8000h
1024B RAM
16b Per.
8b Per.
SFR
05FFh
0200h
01FFh
0100h
00FFh
0010h
000Fh
0000h
1024B RAM
16b Per.
8b Per.
SFR
peripherals
Peripherals are connected to the CPU through a data, address, and controls bus and can be handled easily with
instructions for memory manipulation.
oscillator and system clock
Two clocks are used in the system: the system (master) clock (MCLK) and the auxiliary clock (ACLK). The MCLK
is a multiple of the ACLK. The ACLK runs with the crystal oscillator frequency. The special design of the oscillator
supports the feature of low current consumption and the use of a 32 768 Hz crystal. The crystal is connected
across two terminals without any other external components being required.
The oscillator starts after applying VCC, due to a reset of the control bit (OscOff) in the status register (SR). It
can be stopped by setting the OscOff bit to a 1. The enabled clock signals ACLK, ACLK/2, ACLK/4, or MCLK
are accessible for use by external devices at output terminal XBUF .
The controller system clocks have to deal with different requirements according to the application and system
condition. Requirements include:
D
D
D
D
10
High frequency in order to react quickly to system hardware requests or events
Low frequency in order to minimize current consumption, EMI, etc.
Stable frequency for timer applications e.g. real time clock (RTC)
Enable start-stop operation with minimum delay to operation function
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oscillator and system clock (continued)
These requirements cannot all be met with fast frequency high-Q crystals or with RC-type low-Q oscillators. The
compromise selected for the MSP430 uses a low-crystal frequency which is multiplied to achieve the desired
nominal operating range:
f (system)
+ (N ) 1)
f (crystal)
The crystal frequency multiplication is acheived with a frequency locked loop (FLL) technique. The factor N is
set to 31 after a power-up clear condition. The FLL technique, in combination with a digital controlled oscillator
(DCO), provides immediate start-up capability together with long term crystal stability. The frequency variation
of the DCO with the FLL inactive is typically 330 ppm, which means that with a cycle time of 1 µs the maximum
possible variation is 0.33 ns. For more precise timing, the FLL can be used, which forces longer cycle times if
the previous cycle time was shorter than the selected one. This switching of cycle times makes it possible to
meet the chosen system frequency over a long period of time.
The start-up operation of the system clock depends on the previous machine state. During a PUC, the DCO
is reset to its lowest possible frequency. The control logic starts operation immediately after recognition of PUC.
multiplication
The multiplication operation is supported by a dedicated peripheral module. The module performs 16x16, 16x8,
8x16, and 8x8 bit operations. The module is capable of supporting signed and unsigned multiplication as well
as unsigned multiply and accumulate operations. The result of an operation can be accessed immediately after
the operands have been loaded into the peripheral registers. No additional clock cycles are required.
digital I/O
Five eight-bit I/O ports (P0 thru P4) are implemented. Port P0 has six control registers, P1 and P2 have seven
control registers, and P3 and P4 modules have four control registers to give maximum flexibility of digital
input/output to the application:
D
D
D
D
Individual I/O bits are independently programable.
Any combination of input, output, and interrupt conditions is possible.
Interrupt processing of external events is fully implemented for all eight bits of the P0, P1, and P2 ports.
Read/write access is available to all registers by all instructions.
The seven registers are:
D
D
D
D
D
D
D
Input register
contains information at the pins
Output register
contains output information
Direction register
controls direction
Interrupt edge select
contains input signal change necessary for interrupt
Interrupt flags
indicates if interrupt(s) are pending
Interrupt enable
contains interrupt enable pins
Function select
determines if pin(s) used by module or port
These registers contain eight bits each with the exception of the interrupt flag register and the interrupt enable
register which are 6 bits each. The two least significant bit (LSBs) of the interrupt flag and enable registers are
located in the special function register (SFR). Five interrupt vectors are implemented, one for Port P0.0, one
for Port P0.1, one commonly used for any interrupt event on Port P0.2 to Port P0.7, one commonly used for any
interrupt event on Port P1.0 to Port P1.7, and one commonly used for any interrupt event on Port P2.0 to Port
P2.7.
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LCD drive
Liquid crystal displays (LCDs) for static, 2-, 3-, and 4-MUX operation can be driven directly. The operation of
the controller LCD logic is defined by software through memory-bit manipulation. LCD memory is part of the LCD
module, not part of data memory. Eight mode and control bits define the operation and current consumption of
the LCD drive. The information for the individual digits can be easily obtained using table programming
techniques combined with the proper addressing mode. The segment information is stored into LCD memory
using instructions for memory manipulation.
The drive capability is defined by the external resistor divider that supports analog levels for 2-, 3-, and 4-MUX
operation. Groups of the LCD segment lines can be selected for digital output signals. The MSP430x33x
configuration has four common lines, 30 segment lines, and four terminals for adjusting the analog levels.
Basic Timer1
The Basic Timer1 (BT1) divides the frequency of MCLK or ACLK, as selected with the SSEL bit, to provide low
frequency control signals. This is done within the system by one central divider, the Basic Timer1, to support
low current applications. The BTCTL control register contains the flags which control or select the different
operational functions. When the supply voltage is applied or when a reset of the device (RST/NMI pin), a
watchdog overflow, or a watchdog security key violation occurs, all bits in the register hold undefined or
unchanged status. The user software usually configures the operational conditions on the BT during
initialization.
The Basic Timer1 has two eight bit timers which can be cascaded to a sixteen bit timer. Both timers can be read
and written by software. Two bits in the SFR address range handle the system control interaction according to
the function implemented in the Basic Timer1. These two bits are the Basic Timer1 interrupt flag (BTIFG) and
the Basic Timer1 interrupt enable (BTIE) bit.
Watchdog Timer
The primary function of the Watchdog Timer (WDT) module is to perform a controlled system restart after a
software upset has occurred. If the selected time interval expires, a system reset is generated. If this watchdog
function is not needed in an application, the module can work as an interval timer, which generates an interrupt
after the selected time interval.
The Watchdog Timer counter (WDTCNT) is a 15/16-bit upcounter which is not directly accessible by software.
The WDTCNT is controlled using the Watchdog Timer control register (WDTCTL), which is an 8-bit read/write
register. Writing to WDTCTL, in both operating modes (watchdog or timer) is only possible by using the correct
password in the high-byte. The low-byte stores data written to the WDTCTL. The high-byte password is 05Ah.
If any value other than 05Ah is written to the high-byte of the WDTCTL, a system reset PUC is generated. When
the password is read its value is 069h. This minimizes accidental write operations to the WDTCTL register. In
addition to the Watchdog Timer control bits, there are two bits included in the WDTCTL that configure the NMI
pin.
USART
The universal synchronous/asynchronous interface is a dedicated peripheral module which provides serial
communications. The USART supports synchronous SPI (3 or 4 pin), and asynchronous UART
communications protocols, using double buffered transmit and receive channels. Data streams of 7 or 8 bits
in length can be transferred at a rate determined by the program, or by a rate defined by an external clock. Low
power applications are optimized by UART mode options which allow for the receipt of only the first byte of a
complete frame. The applications software then decides if the succeeding data is to be processed. This option
reduces power consumption.
Two dedicated interrupt vectors are assigned to the USART module, one for the receive and one for the transmit
channel.
12
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Timer/Port
The Timer/Port module has two 8-bit counters, an input that triggers one counter and six digital outputs with
3-state capability. Both counters have an independent clock selector for selecting an external signal or one of
the internal clocks (ACLK or MCLK). One of the counters has an extended control capability to halt, count
continuously, or gate the counter by selecting one of two external signals. This gate signal sets the interrupt flag
if an external signal is selected and the gate stops the counter.
Both timers can be read to and written from by software. The two 8-bit counters can be cascaded to form a 16-bit
counter. A common interrupt vector is implemented. The interrupt flag can be set by three events in the 8-bit
counter mode (gate signal or overflow from the counters) or by two events in the 16-bit counter mode (gate signal
or overflow from the MSB of the cascaded counter).
slope A/D conversion
Slope A/D conversion is accomplished with the Timer/Port module using external resistor(s) for reference (Rref),
external resistor(s) to the measured (Rmeas), and an external capacitor. The external components are driven
by software in such a way that the internal counter measures the time that is needed to charge or discharge
the capacitor.The reference resistor’s (Rref) charge or discharge time is represented by Nref counts. The
unknown resistors (Rmeas) charge or discharge time is represented by Nmeas counts. The unknown resistor’s
value Rmeas is the value of Rref multiplied by the relative number of counts (Nmeas/Nref). This value determines
resistive sensor values that correspond to the physical data, for example temperature, when an NTC or PTC
resistor is used.
Timer_A
The Timer_A module offers one sixteen bit counter and five capture/compare registers. The timer clock source
can be selected to come from an external source TACLK (SSEL=0), the ACLK (SSEL=1), or MCLK (SSEL=2
or SSEL=3). The clock source can be divided by one, two, four or eight. The timer can be fully controlled (in word
mode) since it can be halted, read, and written. It can be stopped, run continuously, count up, or count up/down
using one compare block to determine the period. The five capture/compare blocks are configured by the
application software to run in either capture or compare mode.
The capture mode is primarily used to measure external or internal events with any combination of positive,
negative, or both edges of the clock. The clock can also be stopped in capture mode by software. One external
event (CCISx=0) per capture block can be selected. If CCISx=1, the ACLK is the capture signal; and if CCISx=2
or CCISx=3, software capture is chosen.
The compare mode is primarily used to generate timing for the software or application hardware or to generate
pulse-width modulated output signals for various purposes like D/A conversion functions or motor control. An
individual output module, which can run independently of the compare function or is triggered in several ways,
is assigned to each of the five capture/compare registers.
Two interrupt vectors are used by the Timer_A module. One individual vector is assigned to capture/compare
block CCR0 and one common interrupt vector is assigned to the timer and the other four capture/compare
blocks. The five interrupt events using the common vector are identified by an individual interrupt vector word.
The interrupt vector word is used to add an offset to the program counter to continue the interrupt handler
software at the correct location. This simplifies the interrupt handler and gives each interrupt event the same
interrupt handler overhead of 5 cycles.
8-bit Timer/Counter
The 8-bit interval timer supports three major functions for applications:
D
D
D
Serial communication or data exchange
Plus counting or plus accumulation
Timer
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8-bit Timer/Counter (continued)
The 8-bit Timer/Counter peripheral includes the following major blocks: an 8-bit up-counter with preload register,
an 8-bit control register, an input clock selector, an edge detection (e.g. start bit detection for asynchronous
protocols), and an input and output data latch, triggered by the carry-out-signal from the 8-bit counter.
The 8-bit counter counts up with an input clock, which is selected by two control bits from the control register.
The four possible clock sources are MCLK, ACLK, the external signal from terminal P0.1, and the signal from
the logical AND of MCLK and terminal P0.1.
Two counter inputs (load, enable) control the counter operation. The load input controls load operations. A
write-access to the counter results in loading the content of the preload register into the counter. The software
writes or reads the preload register with all instructions. The preload register acts as a buffer and can be written
immediately after the load of the counter is completed. The enable input enables the count operation. When
the enable signal is set to high, the counter will count-up each time a positive clock edge is applied to the clock
input of the counter.
14
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MSP430C33x, MSP430P337A
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peripheral file map
PERIPHERALS WITH BYTE ACCESS
UART
Transmit buffer, UTXBUF
077h
Port P3 selection, P3SEL
01Bh
Receive buffer, URXBUF
076h
Port P3 direction, P3DIR
01Ah
Baud rate, UBR1
075h
Port P3 output, P3OUT
019h
Baud rate, UBR0
074h
Modulation control, UMCTL
073h
Port P3
Port P0
Port P3 input, P3IN
018h
Port P0 interrupt enable, P0IE
015h
Receive control, URCTL
072h
Port P0 interrupt edge select, P0IES
014h
Transmit control, UTCTL
071h
Port P0 interrupt flag, P0IFG
013h
012h
UART control, UCTL
070h
Port P0 direction, P0DIR
EPROM
EPROM control, EPCTL
054h
Port P0 output, P0OUT
011h
Crystal Buffer
Crystal buffer control, CBCTL
053h
Port P0 input, P0IN
010h
System Clock
SCG frequency control, SCFQCTL
052h
Special
SFR interrupt flag2, IFG2
003h
SCG frequency integrator, SCFI1
051h
Function
SFR interrupt flag1, IFG1
002h
SCG frequency integrator, SCFI0
050h
SFR interrupt enable2, IE2
001h
Timer/Port enable, TPE
04Fh
SFR interrupt enable1, IE1
000h
Timer/Port data, TPD
04Eh
PERIPHERALS WITH WORD ACCESS
Timer/Port counter2, TPCNT2
04Dh
Multiply
Timer/Port
Basic Timer1
8-bit T/C
LCD
Port P1
Port P4
013Eh
013Ch
Timer/Port counter1, TPCNT1
04Ch
Result high word, ResHi
Timer/Port control, TPCTL
04Bh
Result low word, ResLo
013Ah
Basic timer counter2, BTCNT2
047h
Second operand, OP2
0138h
Basic timer counter1, BTCNT1
046h
Reserved
0136h
Basic timer control, BTCTL
040h
Multiply+accumulate/operand1, MAC
0134h
8-bit Timer/Counter data, TCDAT
044h
Multiply signed/operand1, MPYS
0132h
8-bit Timer/Counter preload, TCPLD
043h
Multiply unsigned/operand1, MPY
0130h
8-bit Timer/Counter control, TCCTL
042h
Watchdog
Watchdog Timer control, WDTCTL
0120h
LCD memory 15, LCDM15
03Fh
Timer_A
Timer_A interrupt vector, TAIV
012Eh
Timer_A control, TACTL
0160h
:
Port P2
Sum extend, SumExt
LCD memory 1, LCDM1
031h
Cap/Com control, CCTL0
0162h
LCD control & mode, LCDCTL
030h
Cap/Com control, CCTL1
0164h
Port P2 selection, P2SEL
02Eh
Cap/Com control, CCTL2
0166h
Port P2 interrupt enable, P2IE
02Dh
Cap/Com control, CCTL3
0168h
Port P2 interrupt edge Select, P2IES
02Ch
Cap/Com control, CCTL4
016Ah
Port P2 interrupt flag, P2IFG
02Bh
Reserved
016Ch
Port P2 direction, P2DIR
02Ah
Reserved
016Eh
Port P2 output, P2OUT
029h
Timer_A register, TAR
0170h
Port P2 input, P2IN
028h
Cap/Com register, CCR0
0172h
Port P1 selection, P1SEL
026h
Cap/Com register, CCR1
0174h
Port P1 interrupt enable, P1IE
025h
Cap/Com register, CCR2
0176h
Port P1 interrupt edge Select, P1IES
024h
Cap/Com register, CCR3
0178h
Port P1 interrupt flag, P1IFG
023h
Cap/Com register, CCR4
017Ah
Port P1 direction, P1DIR
022h
Reserved
017Ch
Port P1 output, P1OUT
021h
Reserved
017Eh
Port P1 input, P1IN
020h
Port P4 selection, P4SEL
01Fh
Port P4 direction, P4DIR
01Eh
Port P4 output, P4OUT
01D
Port P4 input, P4IN
01Ch
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
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absolute maximum ratings†
Supply voltage range, between VCC terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 0.3 V
Supply voltage range, between VSS terminals . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 0.3 V
Input voltage range, VCC1 to any VSS terminal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 6 V
Input voltage range, VCC2 to any VSS terminal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 0.3 V to 6 V
Input voltage range to any terminal (referenced to VSS) . . . . . . . . . . . . . . . . . . . . . . . . . . –0.3 V to VCC + 0.3 V
Diode current at any device terminal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±2 mA
Storage temperature range, Tstg, (unprogrammed device) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 55°C to 150°C
Storage temperature range, Tstg, (programmed device) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . – 40°C to 85°C
† Stresses beyond those listed under “absolute maximum ratings” may cause permanent damage to the device. These are stress ratings only, and
functional operation of the device at these or any other conditions beyond those indicated under “recommended operating conditions” is not
implied. Exposure to absolute-maximum-rated conditions for extended periods may affect device reliability.
NOTE: All voltages referenced to VSS.
VCC1
VSS1
Common Lines COM0 to COM3, Segment Lines S0 to S29
Output Drivers O2 to O29
VCC1
VSS1
Core Logic With
Core CPU, System, JTAG/Test,
All Peripheral Modules
J/X
T/B
A/U
G/F
VCC1
VSS1
Terminal of Timer/Port
VSS3
VSS2
VSS1
Input Buffers and Output Drivers of Port P0–P4
Substrate and Ground Potential For Input Inverters/Buffers
(see Note A)
(see Note B)
NOTES: A. Ground potential for all port output drivers and input terminals, excluding first inverter/buffer
B. Ground potential for entire device core logic and peripheral modules
Figure 1. Supply Voltage Interconnection
16
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VCC2
VSS2
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
recommended operating conditions
PARAMETER
MIN
Supply voltage, VCC, (MSP430C33x)
2.5
Supply voltage, VCC, (MSP430E/P33xA)
2.5
Supply voltage, VSS
NOM
MAX
V
5.5
V
0
MSP430C33x, MSP430P33xA
Operating free-air
free air temperature range TA
–40
PMS430E33xA
85
32 768
VCC = 3 V
VCC = 5 V
Processor frequency (signal MCLK),
MCLK) fsystem
t
Low-level input voltage, VIL† (excluding Xin, Xout)
High-level input voltage, VIH† (excluding Xin, Xout)
High-level input voltage, VIH(Xin, Xout)
† A serial resistor of 1 kΩ to the RST/NMI pin is recommended to enhance latch–up immunity.
°C
HZ
DC
1.65
MHz
DC
3.8
MHz
VSS
0.7×VCC
VSS
VSS+0.8
VCC
0.2×VCC1
0.8×VCC1
VCC1
VCC = 3 V/5 V
Low-level input voltage, VIL(Xin, Xout)
– Maximum Processor Frequency – MHz
f (system)
V
25
XTAL frequency f(XTAL) (signal ACLK)
UNIT
5.5
V
V
5
4
3
2
1.1 MHz at
2.5 V
1
0
0
1
2
3
4
5
VCC – Supply Voltage – V
6
7
Figure 2. Processor Frequency vs Supply Voltage
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MSP430C33x, MSP430P337A
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electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted)
supply current (into VCC) excluding external current (f(system) = 1 MHz) (see Note 6)
PARAMETER
I(AM)
NOM
MAX
C336/7
TA= –40°C +85°C,
TA= –40°C +85°C,
TEST CONDITIONS
VCC = 3 V
VCC = 5 V
400
500
800
900
P337A
TA= –40°C +85°C,
TA= –40°C +85°C,
VCC = 3 V
VCC = 5 V
570
700
1170
1250
C336/7
TA= –40°C +85°C,
TA= –40°C +85°C,
VCC = 3 V
VCC = 5 V
50
70
100
130
P337A
TA= –40°C +85°C,
TA= –40°C +85°C,
VCC = 3 V
VCC = 5 V
50
70
100
130
TA= –40°C +85°C,
TA= –40°C +85°C,
VCC = 3 V
VCC = 5 V
7
12
18
25
TA= –40°C
TA= 25°C
2.0
3.5
VCC = 3 V
2.0
3.5
1.6
3.5
5.2
10
4.2
10
Active mode
I(CPUOff)
I(LPM2)
I(LPM3)
Low power mode
mode, (LPM0,1)
(LPM0 1)
mode (LPM2)
Low power mode,
TA= 85°C
TA= –40°C
Low power mode,
mode (LPM3)
TA= 25°C
TA= 85°C
I((LPM4))
TA= –40°C
TA= 25°C
Low power mode, (LPM4)
VCC = 5 V
VCC = 3 V/5 V
MIN
4.0
10
0.1
0.8
0.1
0.8
UNIT
µA
µA
µA
µA
µA
TA= 85°C
0.4
1.5
NOTE 6: All inputs are tied to 0 V or VCC2. Outputs do not source or sink any current. The current consumption in LPM2 and LPM3 are measured
with active Basic Timer1 Module (ACLK selected), LCD Module (fLCD=1024Hz, 4MUX) and USART module (UART, ACLK, 2400 Baud
selected)
Current Consumption of active mode versus system frequency,
IAM = IAM[1MHz] × fsystem[MHz]
Current Consumption of active mode versus supply voltage,
IAM = IAM[3V] + 200µA/V × (VCC–3)
18
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MSP430C33x, MSP430P337A
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electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
schmitt-trigger inputs Port 0 to P4: P0.x to P4.x, Timer/Port: CIN, TP0.5
PARAMETER
VIT+
VIT–
Vhys
y
TEST CONDITIONS
Positive-going input threshold voltage
Negative-going input threshold voltage
Input hysteresis (VIT+–VIT–)
MIN
NOM
MAX
VCC = 3 V
VCC = 5 V
1.2
2.1
2.3
3.4
VCC = 3 V
VCC = 5 V
0.7
1.5
1.4
2.3
VCC = 3 V
VCC = 5 V
0.3
1.0
0.6
1.4
UNIT
V
outputs Port 0 to P4: P0.x to P4.x, Timer/Port: TP0.0 to TP0.5, LCD: S2/O2 to S29/O29, XBUF: XBUF, JTAG:TDO
PARAMETER
VOH
VOL
High level output voltage
High-level
Low level output voltage
Low-level
TEST CONDITIONS
MIN
NOM
MAX
IOH = – 1.2 mA, See Note 7
IOH = – 3.5 mA, See Note 8
VCC = 3 V
VCC–0.4
VCC–1.0
VCC
VCC
IOH = – 1.5 mA, See Note 7
IOH = – 4.5 mA, See Note 8
VCC = 5 V
VCC–0.4
VCC–1.0
VCC
VCC
IOL = + 1.2 mA, See Note 7
IOL = + 3.5 mA, See Note 8
VCC = 3 V
VSS
VSS
VSS+0.4
VSS+1.0
VCC = 5 V
VSS
VSS
VSS+0.4
VSS+1.0
IOL = + 1.5 mA, See Note 7
IOL = + 4.5 mA, See Note 8
UNIT
V
V
NOTES: 7. The maximum total current for all outputs combined should not exceed ±9.6 mA to hold the maximum voltage drop specified.
8. The maximum total current for all outputs combined should not exceed ±28 mA to hold the maximum voltage drop specified.
leakage current (see Note 9)
PARAMETER
TEST CONDITIONS
Ilkg(TP)
High-impendance leakage current,
Timer/Port
Timer/Port:VTP0.x,
VCC = 3 V/5 V,
CIN = VSS, VCC,
(see Note 10)
Ilkg(S27)
High-impendance leakage current, S27
Ilkg(P0x)
Leakage current, port 0
VS27 = VSS to VCC,
Port P0: P0.x, 0 ≤ × ≤ 7,
(see Note 11)
VCC = 3 V/5 V
VCC = 3 V/5 V,
MIN
NOM
MAX
UNIT
± 50
nA
± 50
nA
± 50
nA
NOTES: 9. The leakage current is measured with VSS or VCC applied to the corresponding pins(s) – unless otherwise noted.
10. All Timer/Port pins (TP0.0 to TP0.5) are Hi-Z. Pins CIN and TP0.0 to TP0.5 are connected together during leakage current
measurement. In the leakage measurement mode, the input CIN is included. The input voltage is VSS or VCC.
11. The leakages of the digital port terminals are measured individually. The port terminal must be selected for input and there must
be no optional pullup or pulldown resistor.
POST OFFICE BOX 655303
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19
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
optional resistors (see Note 12)
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
R(opt1)
VCC = 3 V/5 V
1.4
4.1
6.8
kΩ
R(opt2)
VCC = 3 V/5 V
2.1
6.2
11
kΩ
R(opt3)
VCC = 3 V/5 V
VCC = 3 V/5 V
4.2
12
20
kΩ
6.6
19
32
kΩ
VCC = 3 V/5 V
VCC = 3 V/5 V
12
37
62
kΩ
26
75
124
kΩ
VCC = 3 V/5 V
VCC = 3 V/5 V
39
112
185
kΩ
65
187
309
kΩ
VCC = 3 V/5 V
VCC = 3 V/5 V
91
261
431
kΩ
117
337
557
kΩ
MAX
UNIT
R(opt4)
R(opt5)
R(opt6)
Resistors, individually programmable with ROM code, all port
pins, values applicable for pull-down and pull-up
R(opt7)
R(opt8)
R(opt9)
R(opt10)
NOTE 12: Optional resistors R(optx) for pulldown or pullup are not programmed in standard OTP/EPROM devices P/E 337.
inputs and outputs
PARAMETER
CONDITIONS
t(int)
External Interrupt timing
Port P0, P1 to P2:
External trigger signal for the interrupt
flag (see Notes 13 and 14)
t(cap)
Timer_A, Capture timing
TA0-TA4
External capture signal (see Note 15)
f(IN)
t(H) or t(L)
Input frequency
P0.1,
P0
1 CIN,
CIN TP 0.5,
0 5 UCLK,
UCLK SIMO,
SIMO SOMI,
SOMI
TACLK,
TACLK TA0-TA4
t(H) or t(L)
f(XBUF)
f(TAx)
f(UCLK)
Output frequency
t(Xdc)
∆t(TA)
Duty cycle of output
t(τ)
USART: Deglitch time
MIN
NOM
3 V/5 V
1.5
cycle
3 V/5 V
250
ns
3 V/5 V
DC
3V
300
f(system)
f(system)
5V
300
f(system)
f(system)
XBUF, CL = 20 pF
3 V/5 V
TA0-4, CL = 20 pF
3 V/5 V
DC
UCLK, CL = 20 pF
XBUF, CL = 20 pF
f(MCLK)= 1.1 MHz
f(XBUF) = f(ACLK)
f(XBUF) = f(ACLK/n)
TA0..4, CL = 20 pF
t(TAH)= t(TAL)
3 V/5 V
DC
f(system)/2
f(system)
3 V/5 V
3 V/5 V
3 V/5 V
40%
35%
60%
65%
UCLK, C(L) = 15pF
t(UCH)= t(UCL)
∆t(UC)
VCC
ns
MHz
50
3 V/5 V
0
±100
ns
3 V/5 V
0
±100
ns
2.6
1.4
µs
µs
3V
5V
See Note16
MHz
0.6
0.3
NOTES: 13. The external signal sets the interrupt flag every time t(int) is met. It may be set even with trigger signals shorter than t(int). The
conditions to set the flag must be met independently from this timing constraint. T(int) is defined in MCLK cycles.
14. The external interrupt signal cannot exceed the maximum input frequency (f(in))
15. The external capture signal triggers the capture event every time t(cap) is met. It may be triggered even with capture signals shorter
than t(cap). The conditions to set the flag must be met independently from this timing constraint.
16. The signal applied to the USART receive signal/terminal (URXD) should meet the timing requirements of t(τ) to ensure that the URXS
flip-flop is set. The URXS flip-flop is set with negative pulses meeting the minimum timing condition of t(τ). The operating conditions
to set the flag must be met independently from this timing constraint. The deglitch circuitry is active only on negative transitions on
the URXD line.
20
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
LCD
PARAMETER
V(33)
V(23)
TEST CONDITIONS
MIN
Voltage at R33
Analog voltage
V(13)
V(03)
Output 1
Output 0
I(R03)
Input leakage
R13 = VCC/3
R23 = 2 × VCC/3
I(R23)
V(Sxx0)
V(Sxx1)
V(Sxx2)
Segment
line
g
voltage
I(Sxx)
µA,
(S )= – 3 µA
VCC+0.2
V
V(33) – 2.5
I(HLCD)<= 10 nA
I(LLCD) <= 10 nA
UNIT
(V33–V03) × 2/3 + V03
(V(33)–V(03)) × 1/3 + V(03)
VCC = 3 V/5 V
Voltage at R13
R03 = VSS
I(R13)
MAX
2.5
Voltage at R23
Voltage at R03
VO(HLCD)
VO(LLCD)
NOM
VCC+0.2
V(R33) – 0.125
VSS
VCC = 3 V/5 V
VCC
VSS + 0.125
V
±20
No load at all
segmentt and
d
common lines,
VCC = 3 V/5 V
±20
nA
±20
VCC = 3 V/5 V
V(Sxx3)
V(03)
V(13)
V(03) – 0.1
V(13) – 0.1
V(23)
V(33)
V(23) – 0.1
V(33) + 0.1
V
PUC/POR
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
150
250
µs
1.5
2.4
V
1.2
2.1
V
0.9
1.8
V
0
0.4
t(POR) delay
TA = –40°C
TA = 25°C
POR
V(POR)
(
)
VCC = 3 V/5 V
TA = 85°C
V(min)
t(reset)
PUC/POR
Reset is accepted internally
V
µs
2
V
VCC
V
(POR)
V
(min)
POR
No POR
POR
t
Figure 3. Power-On Reset (POR) vs Supply Voltage
POST OFFICE BOX 655303
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21
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
3
2.4
2.5
2.1
V POR [V]
max
1.8
2
1.5
1.5
min
1
1.2
0.9
0.5
25°C
0
–40
–20
0
20
40
60
80
Temperature [°C]
Figure 4. V(POR) vs Temperature
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
crystal oscillator: Xin, Xout
PARAMETER
C(Xin)
Integrated capacitance at input
C(Xout)
Integrated capacitance at output
TEST CONDITIONS
MIN
NOM
VCC = 3V/5V
MAX
UNIT
12
pF
12
pF
DCO
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
DCO
N(DCO) = 1 A0h
FN_4=FN_3=FN_2 = 0
VCC = 3 V/5 V
f(DCO3)
N(DCO) = 00 0110 0000
FN_4=FN_3=FN_2 = 0
VCC = 3 V
VCC = 5 V
0.15
0.6
0.18
0.62
f(DCO26)
N(DCO) = 11 0100 0000
FN_4=FN_3=FN_2 = 0
VCC = 3 V
VCC = 5 V
1.25
4.7
1.45
5.5
f(DCO3)
N(DCO) = 00 0110 0000
FN_4=FN_3=0, FN_2 = 1
VCC = 3 V
VCC = 5 V
0.36
1.05
0.39
1.2
f(DCO26)
N(DCO) = 11 0100 0000
FN_4=FN_3=0, FN_2 = 1
VCC = 3 V
VCC = 5 V
2.5
8.1
3
9.9
f(DCO3)
N(DCO) = 00 0110 0000
FN_4=0, FN_3=1, FN_2=X
VCC = 3 V
VCC = 5 V
0.5
1.5
0.6
1.8
f(DCO26)
N(DCO) = 11 0100 0000
FN_4=0,FN_3 =1, FN_2=X
VCC = 3 V
VCC = 5 V
3.7
11
4.5
13.8
f(DCO3)
N(DCO) = 00 0110 0000
FN_4=1, FN_3 = FN_2=X
VCC = 3 V
VCC = 5 V
0.7
1.85
0.8
2.4
f(DCO26)
N(DCO) = 11 0100 0000
FN_4=1, FN_3 = FN_2=X
VCC = 3 V
VCC = 5 V
4.8
13.3
6
17.7
N(DCO)
f(MCLK) = f(NOM)
FN_4=FN_3=FN_2 = 0
VCC = 3 V/5 V
A0h
S
f(NDCO)+1 = S x f(NDCO)
VCC = 3 V/5 V
1.07
f(NOM)
f(NOM)
2xf(NOM)
3xf(NOM)
4xf(NOM)
22
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1
1A0h
UNIT
MHz
340h
1.13
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
electrical characteristics over recommended and operating free-air temperature range (unless
otherwise noted) (continued)
f(DCO26)
4xfNOM
f(DCO26)
f(DCO3)
3xfNOM
f(DCO26)
f(DCO3)
2xfNOM
Legend
Tolerance at Tap 26
f(DCO26)
DCO Frequency
Adjusted by Bits
2∧9–2∧5 in SCFI1
f(DCO3)
fNOM
Tolerance at Tap 3
f(DCO3)
FN_2 = 0
FN_3 = 0
FN_4 = 0
FN_2 = 1
FN_3 = 0
FN_4 = 0
FN_2 = X
FN_3 = 1
FN_4 = 0
FN_2 = X
FN_3 = X
FN_4 = 1
RAM
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
V(RAMh)
CPU halted (see Note 17)
1.8
V
NOTE 17: This parameter defines the minimum supply voltage when the data in the program memory RAM remains unchanged. No program
execution should happen during this supply voltage condition.
Timer/Port comparator
PARAMETER
TEST CONDITIONS
I(com)
(
)
Comparator (Timer/Port)
Vref(COM)
Internal reference voltage at (–) terminal
Vh
(COM)
hys(COM)
Input hysteresis (comparator)
CPON = 1
VCC = 3 V
VCC = 5 V
CPON = 1
VCC = 3 V/5 V
VCC = 3 V
CPON = 1
VCC = 5 V
POST OFFICE BOX 655303
MIN
NOM
MAX
175
350
600
0.230 × VCC1
• DALLAS, TEXAS 75265
0.260 × VCC1
UNIT
µA
V
5
37
mV
10
42
mV
23
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
electrical characteristics over recommended operating free-air temperature range (unless
otherwise noted) (continued)
JTAG, program memory
PARAMETER
f(TCK)
JTAG/Test
R(test)
V(FB)
I(FB)
t(FB)
JTAG/Fuse
(see Note 19)
NOM
Pullup resistors on TMS, TCK, TDI
(see Note 18)
VCC = 3 V/5 V
25
VCC = 3 V/5 V
VCC = 3 V/5 V
5.5
6.0
11.0
12.0
Fuse blow voltage, E/P versions (see Note 20)
DC
5
DC
10
60
Supply current on TDI/VPP to blow fuse
Programming voltage, applied to TDI/VPP
VCC = 5 V
VCC = 5 V
12.0
VCC = 5 V
VCC = 5 V
5
Programming time, fast algorithm
Number of pulses for successful programming
VCC = 5 V
4
Current from programming voltage source
EPROM(E)
( ) and
OTP(P) versions only
( ) version onlyy
EPROM(E)
MAX
VCC = 3 V
VCC = 5 V
Time to blow the fuse
Pn
t(erase)
MIN
TCK frequency
Fuse blow voltage, C versions (see Note 20)
V(PP)
I(PP)
t(pps)
t(ppf)
TEST CONDITIONS
Programming time, single pulse
12.5
90
UNIT
MHz
kΩ
100
mA
1
ms
13.0
70
V
mA
ms
µs
100
100
Data retention TJ <55°C
10
Year
Erase time wave length 2537 Å at
15 Ws/cm2 (UV lamp of 12 mW/ cm2)
30
min
Write/erase cycles
1000
NOTES: 18. The TMS and TCK pullup resistors are implemented in all ROM(C), OTP(P) and EPROM(E) versions. The pullup resistor on TDI
is implemented in C versions only.
19. Once the fuse is blown no further access to the MSP430 JTAG/test feature is possible.
20. The voltage supply to blow the fuse is applied to TDI/VPP pin during the fuse blowing procedure.
24
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
typical input/output schematics
VCC
VCC
(see Note A)
(see Note A)
(see Note B)
(see Note B)
(see Note B)
(see Note B)
(see Note A)
(see Note A)
GND
GND
CMOS INPUT
CMOS SCHMITT-TRIGGER INPUT
VCC
(see Note A)
(see Note B)
(see Note A)
(see Note B)
GND
I/O WITH SCHMITT-TRIGGER INPUT
CMOS 3-STATE OUTPUT
TDO_Internal
VCC
60 k TYP
TDO_Control
TDI_Control
TDI_Internal
MSP430C336/337: TMS, TCK, TDI
MSP430P/E337A: TMS, TCK
MSP430C33x: TDO/TDI
MSP430P/E337A: TDO/TDI
NOTES: A. Optional selection of pullup or pulldown resistors available on ROM (masked) versions.
B. Fuses for the optional pullup and pulldown resistors can only be programmed at the factory.
POST OFFICE BOX 655303
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25
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
typical input/output schematics
VC
COM 0–3
VD
Control COM0–3
VA
S0, S1
VB
Segment contol
VA
S2/O2–Sn/On
VB
Non-Inverting
Segment control
LCDCTL (LCDM5,6,7)
Data (LCD RAM bits 0–3
or bits 4–7)
LCD OUTPUT (COM0–4, Sn, Sn/On)
NOTE A: The signals VA, VB, VC, and VD come from the LCD module analog voltage generator.
VPP_ Internal
TDI_ Internal
TDI/VPP
JTAG
Fuse
TDO/TDI_Control
TDO/TDI
TMS
TDO_ Internal
JTAG Fuse
Blow
Control
From/To JTAG_CBT_SIG_REG
NOTES: A. During programming activity and when blowing the JTAG enable fuse, the TDI/VPP terminal is used to apply the correct voltage
source. The TDO/TDI terminal is used to apply the test input data for JTAG circuitry.
B. The TDI/VPP terminal of the ’P337A and ’E337A does not have an internal pullup resistor. An external pulldown resistor is
recommended to avoid a floating node, which could increase the current consumption of the device. Remove the external
pulldown resistors when switching from P/E337A to C337 devices. Otherwise system power consumption will increase.
C. The TDO/TDI terminal is in a high-impedance state after POR. The ’P337A and ’E337A need a pullup or a pulldown resistor to
avoid floating a node, which could increase the current consumption of the device.
Figure 5. MSP430P/E337A: TDI/VPP, TDO/TDI
26
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MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
JTAG fuse check mode
MSP430 devices that have the fuse on the TDI/VPP terminal have a fuse check mode that tests the continuity
of the fuse the first time the JTAG port is accessed after a power-on reset (POR). When activated, a fuse check
current, ITF, of 1 mA at 3 V, 2.5 mA at 5 V can flow from the TDI/VPP pin to ground if the fuse is not burned. Care
must be taken to avoid accidentally activating the fuse check mode and increasing overall system power
consumption.
Activation of the fuse check mode occurs with the first negative edge on the TMS pin. The second positive edge
on the TMS pin deactivates the fuse check mode. After deactivation, the fuse check mode remains inactive until
another POR occurs. After each POR the fuse check mode has the potential to be activated.
Fuse check current may or may not flow continuously while the fuse check mode is active, depending on which
type of device is in use and the state of the TMS pin.
For the mask ROM or C versions, the fuse check current will only flow when the fuse check mode is active and
the TMS pin is in a low state (see Figure 6). Therefore, the additional current flow can be prevented by holding
the TMS pin high (default condition).
Time TMS Goes Low After POR
TMS
ITDI
ITF
Figure 6. Fuse Check Mode Current, MSP430C33xA
For the OTP or P versions, the fuse check current will flow continuously when fuse check mode is active,
regardless of the state of the TMS pin, until the fuse check mode is deactivated with the second positive edge
at the TMS pin (see Figure 7).
Time TMS Goes Low After POR
TMS
ITDI
ITF
Figure 7. Fuse Check Mode Current, MSP430P337A
Care must be taken to avoid accidentally activating the fuse check mode, including guarding against EMI/ESD
spikes that could cause signal edges on the TMS pin.
Configuration of TMS, TCK, TDI/VPP and TDO/TDI pins in applications.
C3xx
P/E3xx
TDI
Open
68k, pull down
TDO
Open
68k, pull down
TMS
Open
Open
TCK
Open
Open
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27
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
MECHANICAL DATA
PJM (R-PQFP-G100)
PLASTIC QUAD FLATPACK
0,38
0,22
0,65
80
0,13 M
51
50
81
12,35 TYP
100
14,20
13,80
17,45
16,95
31
1
30
0,16 NOM
18,85 TYP
20,20
19,80
23,45
22,95
2,90
2,50
Gage Plane
0,25
0,25 MIN
0°– 7°
1,03
0,73
Seating Plane
0,10
3,40 MAX
4040022 / B 03/95
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
C. Falls within JEDEC MS-022
28
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• DALLAS, TEXAS 75265
MSP430C33x, MSP430P337A
MIXED SIGNAL MICROCONTROLLERS
SLAS227 – OCTOBER 1999
MECHANICAL DATA
HFD (S-GQFP-G100)
CERAMIC QUAD FLATPACK
0,65
0,30 TYP
80
51
81
50
12,35 TYP
100
14,20
13,80
17,45
16,95
31
1
30
0,15 TYP
18,85 TYP
20,20
19,20
3,70 TYP
23,45
22,95
0,10 MIN
0°– 8°
1,00
0,60
Seating Plane
0,10
4,25 MAX
4081530/A 09/95
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
29
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Copyright  1999, Texas Instruments Incorporated
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