TI MSP430FG439

SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
D Low Supply-Voltage Range, 1.8 V to 3.6 V
D Ultralow-Power Consumption:
D
D
D
D
D
D
D
D
D
D
D
− Active Mode: 300 µA at 1 MHz, 2.2 V
− Standby Mode: 1.1 µA
− Off Mode (RAM Retention): 0.1 µA
Five Power Saving Modes
Wake-Up From Standby Mode in less
than 6 µs
16-Bit RISC Architecture,
125-ns Instruction Cycle Time
Single-Channel Internal DMA
12-Bit A/D Converter With Internal
Reference, Sample-and-Hold and Autoscan
Feature
Three Configurable Operational Amplifiers
Dual 12-Bit D/A Converters With
Synchronization
16-Bit Timer_A With Three
Capture/Compare Registers
16-Bit Timer_B With Three
Capture/Compare-With-Shadow Registers
On-Chip Comparator
Serial Communication Interface (USART),
Select Asynchronous UART or
Synchronous SPI by Software
D Brownout Detector
D Supply Voltage Supervisor/Monitor With
Programmable Level Detection
D Bootstrap Loader
D Serial Onboard Programming,
D
D
D
No External Programming Voltage Needed
Programmable Code Protection by Security
Fuse
Integrated LCD Driver for Up to
128 Segments
Family Members Include:
− MSP430FG437:
32KB+256B Flash Memory,
1KB RAM
− MSP430FG438:
48KB+256B Flash Memory,
2KB RAM
− MSP430FG439:
60KB+256B Flash Memory,
2KB RAM
For Complete Module Descriptions, See
The MSP430x4xx Family User’s Guide,
Literature Number SLAU056
description
The Texas Instruments MSP430 family of ultralow power microcontrollers consist of several devices featuring
different sets of peripherals targeted for various applications. The architecture, combined with five low power
modes is optimized to achieve extended battery life in portable measurement applications. The device features
a powerful 16-bit RISC CPU, 16-bit registers, and constant generators that attribute to maximum code efficiency.
The digitally controlled oscillator (DCO) allows wake-up from low-power modes to active mode in less than 6µs.
The MSP430FG43x series are microcontroller configurations with two 16-bit timers, a high performance 12-bit
A/D converter, dual 12-bit D/A converters, three configurable operational amplifiers, one universal
synchronous/asynchronous communication interface (USART), DMA, 48 I/O pins, and a liquid crystal display
(LCD) driver.
Typical applications for this device include analog and digital sensor systems, digital motor control, remote
controls, thermostats, digital timers, hand-held meters, etc.
This integrated circuit can be damaged by ESD. Texas Instruments recommends that all integrated circuits be handled with
appropriate precautions. Failure to observe proper handling and installation procedures can cause damage. ESD damage can range
from subtle performance degradation to complete device failure. Precision integrated circuits may be more susceptible to damage
because very small parametric changes could cause the device not to meet its published specifications. These devices have limited
built-in ESD protection.
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  2004, Texas Instruments Incorporated
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AVAILABLE OPTIONS
PACKAGED DEVICES
TA
PLASTIC 80-PIN QFP
(PN)
MSP430FG437IPN
MSP430FG438IPN
MSP430FG439IPN
−40°C to 85°C
AVCC
DVSS1
AVSS
P6.2/A2/OA0I1
P6.1/A1/OA0O
P6.0/A0/OA0I0
RST/NMI
TCK
TMS
TDI/TCLK
TDO/TDI
XT2IN
XT2OUT
P1.0/TA0
P1.1/TA0/MCLK
P1.2/TA1
P1.3/TBOUTH/SVSOUT
PN PACKAGE
(TOP VIEW)
P1.4/TBCLK/SMCLK
P1.5/TACLK/ACLK
P1.6/CA0
pin designation, MSP430FG437IPN, MSP430FG438IPN, MSP430FG439IPN
80 79 78 77 76 75 74 73 72 71 70 69 68 67 66 65 64 63 62 61
1
60
2
59
3
58
4
57
5
56
6
55
7
54
8
53
9
52
10
MSP430FG43xIPN
51
11
50
12
49
13
48
14
47
15
46
16
45
17
44
18
43
19
42
20
41
21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40
P4.0/S9
S10
S11
S12
S13
S14
S15
S16
S17
P2.7/ADC12CLK/S18
P2.6/CAOUT/S19
S20
S21
S22
S23
P3.7/S24
P3.6/S25/DMAE0
P3.5/S26
P3.4/S27
P3.3/UCLK0/S28
DVCC1
P6.3/A3/OA1I1/OA1O
P6.4/A4/OA1I0
P6.5/A5/OA2I1/OA2O
P6.6/A6/DAC0/OA2I0
P6.7/A7/DAC1/SVSIN
VREF+
XIN
XOUT
VeREF+/DAC0
VREF−/VeREF−
P5.1/S0/A12/DAC1
P5.0/S1/A13
P4.7/S2/A14
P4.6/S3/A15
P4.5/S4
P4.4/S5
P4.3/S6
P4.2/S7
P4.1/S8
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P1.7/CA1
P2.0/TA2
P2.1/TB0
P2.2/TB1
P2.3/TB2
P2.4/UTXD0
P2.5/URXD0
DVSS2
DVCC2
P5.7/R33
P5.6/R23
P5.5/R13
R03
P5.4/COM3
P5.3/COM2
P5.2/COM1
COM0
P3.0/STE0/S31
P3.1/SIMO0/S30
P3.2/SOMI0/S29
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
MSP430FG43x functional block diagrams
XIN
XOUT
DVCC1/2 DVSS1/2 AVCC
P1
AVSS RST/NMI
P2
8
Oscillator
XT2IN
FLL+
ACLK
60KB Flash
2KB RAM
SMCLK 48KB Flash
2KB RAM
32KB Flash
1KB RAM
XT2OUT
ADC12
12-Bit
12
Channels
<10µs Conv.
P3/P4 P5/P6
8
I/O Port 1/2
16 I/Os,
with
Interrupt
Capability
DAC12
12-Bit
2 Channels
Voltage out
16
16
I/O Port 3/4
16 I/Os
I/O Port 5/6
16 I/Os
OA0, OA1,
OA2
3 Op Amps
USART0
UART Mode
SPI Mode
MCLK
Test
MAB,
4 Bit
MAB,MAB,
16 Bit16-Bit
JTAG
CPU
MCB
Emulation
Module
Incl. 16 Reg.
Bus
Conv
MDB,
16-Bit
MDB,
16 Bit
MDB, 8 Bit
4
TMS
TCK
TDI/TCLK
TDO/TDI
DMA
Controller
1 Channel
Watchdog
Timer
15/16-Bit
Timer_B3
Timer_A3
3 CC Reg
Shadow
Reg
3 CC Reg
POR
SVS
Brownout
Comparator
A
Basic
Timer 1
1 Interrupt
Vector
LCD
128
Segments
1,2,3,4 MUX
fLCD
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MSP430FG43x Terminal Functions
TERMINAL
PN
NAME
NO.
DESCRIPTION
I/O
DVCC1
1
P6.3/A3/OA1I1/OA1O
2
I/O
General-purpose digital I/O / analog input a3—12-bit ADC / OA1 output and/or input multiplexer on
+terminal and −terminal
P6.4/A4/OA1I0
3
I/O
General-purpose digital I/O / analog input a4—12-bit ADC / OA1 input multiplexer on +terminal and
−terminal
P6.5/A5/OA2I1/OA2O
4
I/O
General-purpose digital I/O / analog input a5—12-bit ADC / OA2 output and/or input multiplexer on
+terminal and −terminal
P6.6/A6/DAC0/OA2I0
5
I/O
General-purpose digital I/O / analog input a6—12-bit ADC / DAC12.0 output / OA2 input multiplexer
on +terminal and −terminal
P6.7/A7/DAC1/
SVSIN
6
I/O
General-purpose digital I/O / analog input a7—12-bit ADC / DAC12.1 output/analog input to supply
voltage supervisor
VREF+
XIN
7
O
Positive output terminal of the reference voltage in the ADC
8
I
Input terminal of crystal oscillator XT1
XOUT
9
O
Output terminal of crystal oscillator XT1
VeREF+/DAC0
10
I
Positive input terminal for an external reference voltage to the 12-bit ADC/DAC12.0 output
VREF−/VeREF−
11
I
Negative terminal for the 12-bit ADC’s reference voltage for both sources, the internal reference
voltage or an external applied reference voltage to the 12-bit ADC.
P5.1/S0/A12/DAC1
12
I/O
General-purpose digital I/O / LCD segment output 0/ analog input a12—12-bit ADC/DAC12.1 output
P5.0/S1/A13
13
I/O
General-purpose digital I/O / LCD segment output 1/ analog input a13—12-bit ADC
P4.7/S2/A14
14
I/O
General-purpose digital I/O / LCD segment output 2/ analog input a14—12-bit ADC
P4.6/S3/A15
15
I/O
General-purpose digital I/O / LCD segment output 3/ analog input a15—12-bit ADC
P4.5/S4
16
I/O
General-purpose digital I/O / LCD segment output 4
P4.4/S5
17
I/O
General-purpose digital I/O / LCD segment output 5
P4.3/S6
18
I/O
General-purpose digital I/O / LCD segment output 6
P4.2/S7
19
I/O
General-purpose digital I/O / LCD segment output 7
P4.1/S8
20
I/O
General-purpose digital I/O / LCD segment output 8
P4.0/S9
21
I/O
General-purpose digital I/O / LCD segment output 9
S10
22
O
LCD segment output 10
S11
23
O
LCD segment output 11
S12
24
O
LCD segment output 12
S13
25
O
LCD segment output 13
S14
26
O
LCD segment output 14
S15
27
O
LCD segment output 15
S16
28
O
LCD segment output 16
S17
29
O
LCD segment output 17
P2.7/ADC12CLK/S18
30
I/O
General-purpose digital I/O / conversion clock—12-bit ADC / LCD segment output 18
P2.6/CAOUT/S19
31
I/O
General-purpose digital I/O / Comparator_A output / LCD segment output 19
S20
32
O
LCD segment output 20
S21
33
O
LCD segment output 21
S22
34
O
LCD segment output 22
S23
35
O
LCD segment output 23
P3.7/S24
36
I/O
General-purpose digital I/O / LCD segment output 24
P3.6/S25/DMAE0
37
I/O
General-purpose digital I/O / LCD segment output 25/DMA Channel 0 external trigger
P3.5/S26
38
I/O
General-purpose digital I/O / LCD segment output 26
P3.4/S27
39
I/O
General-purpose digital I/O / LCD segment output 27
4
Digital supply voltage, positive terminal.
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MSP430FG43x Terminal Functions (Continued)
TERMINAL
PN
NAME
NO.
DESCRIPTION
I/O
P3.3/UCLK0/S28
40
I/O
General-purpose digital I/O / ext. clock i/p—USART0/UART or SPI mode, clock o/p—USART0/SPI mode
/ LCD segment output 28
P3.2/SOMI0/S29
41
I/O
General-purpose digital I/O / slave out/master in of USART0/SPI mode / LCD segment output 29
P3.1/SIMO0/S30
42
I/O
General-purpose digital I/O / slave out/master out of USART0/SPI mode / LCD segment output 30
P3.0/STE0/S31
43
I/O
General-purpose digital I/O / slave transmit enable-USART0/SPI mode / LCD segment output 31
COM0
44
O
Common output, COM0−3 are used for LCD backplanes.
P5.2/COM1
45
I/O
General-purpose digital I/O / common output, COM0−3 are used for LCD backplanes.
P5.3/COM2
46
I/O
General-purpose digital I/O / common output, COM0−3 are used for LCD backplanes.
P5.4/COM3
47
I/O
General-purpose digital I/O / common output, COM0−3 are used for LCD backplanes.
R03
48
I
P5.5/R13
49
I/O
General-purpose digital I/O / input port of third most positive analog LCD level (V4 or V3)
P5.6/R23
50
I/O
General-purpose digital I/O / input port of second most positive analog LCD level (V2)
P5.7/R33
51
I/O
General-purpose digital I/O / output port of most positive analog LCD level (V1)
DVCC2
52
DVSS2
53
P2.5/URXD0
54
I/O
General-purpose digital I/O / receive data in—USART0/UART mode
P2.4/UTXD0
55
I/O
General-purpose digital I/O / transmit data out—USART0/UART mode
P2.3/TB2
56
I/O
General-purpose digital I/O / Timer_B3 CCR2.
Capture: CCI2A/CCI2B input, compare: Out2 output
P2.2/TB1
57
I/O
General-purpose digital I/O / Timer_B3 CCR1.
Capture: CCI1A/CCI1B input, compare: Out1 output
P2.1/TB0
58
I/O
General-purpose digital I/O / Timer_B3 CCR0.
Capture: CCI0A/CCI0B input, compare: Out0 output
P2.0/TA2
59
I/O
General-purpose digital I/O / Timer_A
Capture: CCI2A input, compare: Out2 output
P1.7/CA13
60
I/O
General-purpose digital I/O / Comparator_A input
P1.6/CA0
61
I/O
General-purpose digital I/O / Comparator_A input
P1.5/TACLK/
ACLK
62
I/O
General-purpose digital I/O / Timer_A, clock signal TACLK input /
ACLK output (divided by 1, 2, 4, or 8)
P1.4/TBCLK/
SMCLK
63
I/O
General-purpose digital I/O / input clock TBCLK—Timer_B3 / submain system clock SMCLK output
P1.3/TBOUTH/
SVSOUT
64
I/O
General-purpose digital I/O / switch all PWM digital output ports to high impedance—Timer_B3 TB0 to TB2
/ SVS: output of SVS comparator
P1.2/TA1
65
I/O
General-purpose digital I/O / Timer_A, Capture: CCI1A, compare: Out1 output
P1.1/TA0/MCLK
66
I/O
General-purpose digital I/O / Timer_A. Capture: CCI0B / MCLK output. Note: TA0 is only an input on this
pin / BSL receive
P1.0/TA0
67
I/O
General-purpose digital I/O / Timer_A. Capture: CCI0A input, compare: Out0 output / BSL transmit
XT2OUT
68
O
Output terminal of crystal oscillator XT2
XT2IN
69
I
Input port for crystal oscillator XT2. Only standard crystals can be connected.
TDO/TDI
70
I/O
TDI/TCLK
71
I
Test data input or test clock input. The device protection fuse is connected to TDI/TCLK.
TMS
72
I
Test mode select. TMS is used as an input port for device programming and test.
TCK
73
I
Test clock. TCK is the clock input port for device programming and test.
Input port of fourth positive (lowest) analog LCD level (V5)
Digital supply voltage, positive terminal.
Digital supply voltage, negative terminal.
Test data output port. TDO/TDI data output or programming data input terminal
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MSP430FG43x Terminal Functions (Continued)
TERMINAL
PN
NAME
NO.
DESCRIPTION
I/O
RST/NMI
74
I
P6.0/A0/OA0I0
75
I/O
General-purpose digital I/O / analog input a0 − 12-bit ADC / OA0 input multiplexer on +terminal and
− terminal
P6.1/A1/OA0O
76
I/O
General-purpose digital I/O / analog input a1 − 12-bit ADC / OA0 output
P6.2/A2/OA0I1
77
I/O
General-purpose digital I/O / analog input a2 − 12-bit ADC / OA0 input multiplexer on + terminal and
− terminal
AVSS
78
Analog supply voltage, negative terminal. Supplies SVS, brownout, oscillator, FLL+, comparator_A,
port 1, and LCD resistive divider circuitry.
DVSS1
79
Digital supply voltage, negative terminal.
AVCC
80
Analog supply voltage, positive terminal. Supplies SVS, brownout, oscillator, FLL+, comparator_A,
port 1, and LCD resistive divider circuitry; must not power up prior to DVCC1/DVCC2.
6
Reset or nonmaskable interrupt input
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short-form description
CPU
The MSP430 CPU has a 16-bit RISC architecture
that is highly transparent to the application. All
operations, other than program-flow instructions,
are performed as register operations in
conjunction with seven addressing modes for
source operand and four addressing modes for
destination operand.
Program Counter
PC/R0
Stack Pointer
SP/R1
SR/CG1/R2
Status Register
Constant Generator
The CPU is integrated with 16 registers that
provide reduced instruction execution time. The
register-to-register operation execution time is
one cycle of the CPU clock.
Four of the registers, R0 to R3, are dedicated as
program counter, stack pointer, status register,
and constant generator respectively. The
remaining registers are general-purpose
registers.
Peripherals are connected to the CPU using data,
address, and control buses, and can be handled
with all instructions.
instruction set
The instruction set consists of 51 instructions with
three formats and seven address modes. Each
instruction can operate on word and byte data.
Table 1 shows examples of the three types of
instruction formats; the address modes are listed
in Table 2.
CG2/R3
General-Purpose Register
R4
General-Purpose Register
R5
General-Purpose Register
R6
General-Purpose Register
R7
General-Purpose Register
R8
General-Purpose Register
R9
General-Purpose Register
R10
General-Purpose Register
R11
General-Purpose Register
R12
General-Purpose Register
R13
General-Purpose Register
R14
General-Purpose Register
R15
Table 1. Instruction Word Formats
Dual operands, source-destination
e.g. ADD R4,R5
R4 + R5 −−−> R5
Single operands, destination only
e.g. CALL
PC −−>(TOS), R8−−> PC
Relative jump, un/conditional
e.g. JNE
R8
Jump-on-equal bit = 0
Table 2. Address Mode Descriptions
ADDRESS MODE
S D
SYNTAX
EXAMPLE
OPERATION
Register
F F
MOV Rs,Rd
MOV R10,R11
Indexed
F F
MOV X(Rn),Y(Rm)
MOV 2(R5),6(R6)
Symbolic (PC relative)
F F
MOV EDE,TONI
M(EDE) —> M(TONI)
Absolute
F F
MOV &MEM, &TCDAT
M(MEM) —> M(TCDAT)
R10
—> R11
M(2+R5)—> M(6+R6)
Indirect
F
MOV @Rn,Y(Rm)
MOV @R10,Tab(R6)
M(R10) —> M(Tab+R6)
Indirect
autoincrement
F
MOV @Rn+,Rm
MOV @R10+,R11
M(R10) —> R11
R10 + 2—> R10
F
MOV #X,TONI
MOV #45,TONI
Immediate
NOTE: S = source
#45
—> M(TONI)
D = destination
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operating modes
The MSP430 has one active mode and five software selectable low-power modes of operation. An interrupt
event can wake up the device from any of the five low-power modes, service the request and restore back to
the low-power mode on return from the interrupt program.
The following six operating modes can be configured by software:
D Active mode AM;
−
All clocks are active
D Low-power mode 0 (LPM0);
−
CPU is disabled
ACLK and SMCLK remain active. MCLK is disabled
FLL+ Loop control remains active
D Low-power mode 1 (LPM1);
−
CPU is disabled
FLL+ Loop control is disabled
ACLK and SMCLK remain active. MCLK is disabled
D Low-power mode 2 (LPM2);
−
CPU is disabled
MCLK and FLL+ loop control and DCOCLK are disabled
DCO’s dc-generator remains enabled
ACLK remains active
D Low-power mode 3 (LPM3);
−
CPU is disabled
MCLK, FLL+ loop control, and DCOCLK are disabled
DCO’s dc-generator is disabled
ACLK remains active
D Low-power mode 4 (LPM4);
−
8
CPU is disabled
ACLK is disabled
MCLK, FLL+ loop control, and DCOCLK are disabled
DCO’s dc-generator is disabled
Crystal oscillator is stopped
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interrupt vector addresses
The interrupt vectors and the power-up starting address are located in the address range 0FFFFh − 0FFE0h.
The vector contains the 16-bit address of the appropriate interrupt-handler instruction sequence.
INTERRUPT SOURCE
INTERRUPT FLAG
SYSTEM INTERRUPT
WORD
ADDRESS
PRIORITY
Power-Up
External Reset
Watchdog
Flash Memory
WDTIFG
KEYV
(see Note 1)
Reset
0FFFEh
15, highest
NMI
Oscillator Fault
Flash Memory Access Violation
NMIIFG (see Notes 1 and 3)
OFIFG (see Notes 1 and 3)
ACCVIFG (see Notes 1 and 3)
(Non)maskable
(Non)maskable
(Non)maskable
0FFFCh
14
Timer_B3
TBCCR0 CCIFG0 (see Note 2)
Maskable
0FFFAh
13
Timer_B3
TBCCR1 CCIFG1, TBCCR2 CCIFG2,
TBIFG (see Notes 1 and 2)
Maskable
0FFF8h
12
Comparator_A
CAIFG
Maskable
0FFF6h
11
Watchdog Timer
WDTIFG
Maskable
0FFF4h
10
USART0 Receive
URXIFG0
Maskable
0FFF2h
9
USART0 Transmit
UTXIFG0
Maskable
0FFF0h
8
ADC12
ADC12IFG (see Notes 1 and 2)
Maskable
0FFEEh
7
Timer_A3
TACCR0 CCIFG0 (see Note 2)
Maskable
0FFECh
6
Timer_A3
TACCR1 CCIFG1 and TACCR2 CCIFG2,
TAIFG (see Notes 1 and 2)
Maskable
0FFEAh
5
I/O Port P1 (Eight Flags)
P1IFG.0 to P1IFG.7 (see Notes 1 and 2)
Maskable
0FFE8h
4
DAC12
DMA
DAC12.0IFG, DAC12.1IFG,
DMA0IFG (see Notes 1 and 2)
Maskable
0FFE6h
3
0FFE4h
2
I/O Port P2 (Eight Flags)
P2IFG.0 to P2IFG.7 (see Notes 1 and 2)
Maskable
0FFE2h
1
Basic Timer1
BTIFG
Maskable
0FFE0h
0, lowest
NOTES: 1. Multiple source flags
2. Interrupt flags are located in the module.
3. (Non)maskable: the individual interrupt-enable bit can disable an interrupt event, but the general-interrupt enable cannot
disable it.
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special function registers
The MSP430 special function registers(SFR) are located in the lowest address space, and are organized as
byte mode registers. SFRs should be accessed with byte instructions.
interrupt enable 1 and 2
7
Address
0h
6
UTXIE0
rw–0
URXIE0
rw–0
5
4
ACCVIE
NMIIE
rw–0
3
2
1
OFIE
rw–0
rw–0
Watchdog-timer interrupt enable. Inactive if watchdog mode is selected.
Active if watchdog timer is configured as a general-purpose timer.
OFIE:
Oscillator-fault-interrupt enable
NMIIE:
Nonmaskable-interrupt enable
ACCVIE:
Flash access violation interrupt enable
URXIE0:
USART0: UART and SPI receive-interrupt enable
UTXIE0:
USART0: UART and SPI transmit-interrupt enable
7
6
5
WDTIE
rw–0
WDTIE:
Address
0
4
3
2
1
0
4
3
2
1
0
BTIE
01h
rw–0
BTIE:
Basic timer interrupt enable
interrupt flag register 1 and 2
7
Address
02h
6
UTXIFG0
rw–1
5
URXIFG0
NMIIFG
rw–0
OFIFG
rw–0
rw–1
rw–(0)
WDTIFG:
Set on watchdog timer overflow (in watchdog mode) or security key violation
Reset on VCC power-on or a reset condition at the RST/NMI pin in reset mode
OFIFG:
Flag set on oscillator fault
NMIIFG:
Set via RST/NMI pin
URXIFG0:
USART0: UART and SPI receive flag
UTXIFG0:
USART0: UART and SPI transmit flag
7
Address
03h
6
5
4
3
BTIFG
rw–0
BTIFG:
10
WDTIFG
Basic timer flag
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module enable registers 1 and 2
7
UTXE0
Address
04h
rw–0
6
URXE0
USPIE0
5
4
3
1
0
2
1
0
rw–0
URXE0:
USART0: UART mode receive enable
UTXE0:
USART0: UART mode transmit enable
USPIE0:
USART0: SPI mode transmit and receive enable
Address
2
7
6
5
4
3
05h
Legend: rw:
rw–0,1:
rw–(0,1):
Bit Can Be Read and Written
Bit Can Be Read and Written. It Is Reset or Set by PUC.
Bit Can Be Read and Written. It Is Reset or Set by POR.
SFR Bit Not Present in Device
memory organization
MSP430FG437
MSP430FG438
MSP430FG439
Memory
Main: interrupt vector
Main: code memory
Size
Flash
Flash
32KB
0FFFFh − 0FFE0h
0FFFFh − 08000h
48KB
0FFFFh − 0FFE0h
0FFFFh − 04000h
60KB
0FFFFh − 0FFE0h
0FFFFh − 01100h
Information memory
Size
Flash
256 Byte
010FFh − 01000h
256 Byte
010FFh − 01000h
256 Byte
010FFh − 01000h
Boot memory
Size
ROM
1KB
0FFFh − 0C00h
1KB
0FFFh − 0C00h
1KB
0FFFh − 0C00h
Size
1KB
05FFh − 0200h
2KB
09FFh − 0200h
2KB
09FFh − 0200h
16-bit
8-bit
8-bit SFR
01FFh − 0100h
0FFh − 010h
0Fh − 00h
01FFh − 0100h
0FFh − 010h
0Fh − 00h
01FFh − 0100h
0FFh − 010h
0Fh − 00h
RAM
Peripherals
bootstrap loader (BSL)
The MSP430 bootstrap loader (BSL) enables users to program the flash memory or RAM using a UART serial
interface. Access to the MSP430 memory via the BSL is protected by user-defined password. For complete
description of the features of the BSL and its implementation, see the Application report Features of the MSP430
Bootstrap Loader, Literature Number SLAA089.
BSL Function
PN Package Pins
Data Transmit
67 − P1.0
Data Receive
66 − P1.1
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flash memory
The flash memory can be programmed via the JTAG port, the bootstrap loader, or in-system by the CPU. The
CPU can perform single-byte and single-word writes to the flash memory. Features of the flash memory include:
D Flash memory has n segments of main memory and two segments of information memory (A and B) of 128
bytes each. Each segment in main memory is 512 bytes in size.
D Segments 0 to n may be erased in one step, or each segment may be individually erased.
D Segments A and B can be erased individually, or as a group with segments 0−n.
Segments A and B are also called information memory.
D New devices may have some bytes programmed in the information memory (needed for test during
manufacturing). The user should perform an erase of the information memory prior to the first use.
32KB
48KB
60KB
0FFFFh
0FFFFh
0FFFFh
0FE00h
0FDFFh
0FE00h
0FDFFh
0FE00h
0FDFFh
Segment 1
0FC00h
0FBFFh
0FC00h
0FBFFh
0FC00h
0FBFFh
Segment 2
0FA00h
0F9FFh
0FA00h
0F9FFh
0FA00h
0F9FFh
08400h
083FFh
04400h
043FFh
01400h
013FFh
08200h
081FFh
04200h
041FFh
01200h
011FFh
08000h
010FFh
04000h
010FFh
01100h
010FFh
01080h
0107Fh
01080h
0107Fh
01080h
0107Fh
01000h
01000h
01000h
Segment 0
w/ Interrupt Vectors
Main
Memory
Segment n-1
Segment n†
Segment A
Information
Memory
Segment B
† MSP430FG439 flash segment n = 256 bytes.
12
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peripherals
Peripherals are connected to the CPU through data, address, and control busses and can be handled using
all instructions. For complete module descriptions, refer to the MSP430x4xx Family User’s Guide, Literature
Number SLAU056.
DMA controller
The DMA controller allows movement of data from one memory address to another without CPU intervention.
For example, the DMA controller can be used to move data from the ADC12 conversion memory to RAM. Using
the DMA controller can increase the throughput of peripheral modules. The DMA controller reduces system
power consumption by allowing the CPU to remain in sleep mode without having to awaken to move data to
or from a peripheral.
oscillator and system clock
The clock system in the MSP430FG43x family of devices is supported by the FLL+ module that includes support
for a 32768 Hz watch crystal oscillator, an internal digitally-controlled oscillator (DCO) and a high frequency
crystal oscillator. The FLL+ clock module is designed to meet the requirements of both low system cost and
low-power consumption. The FLL+ features digital frequency locked loop (FLL) hardware which in conjunction
with a digital modulator stabilizes the DCO frequency to a programmable multiple of the watch crystal frequency.
The internal DCO provides a fast turn-on clock source and stabilizes in less than 6 µs. The FLL+ module
provides the following clock signals:
D
D
D
D
Auxiliary clock (ACLK), sourced from a 32768 Hz watch crystal or a high frequency crystal.
Main clock (MCLK), the system clock used by the CPU.
Sub-Main clock (SMCLK), the sub-system clock used by the peripheral modules.
ACLK/n, the buffered output of ACLK, ACLK/2, ACLK/4, or ACLK/8.
brownout, supply voltage supervisor
The brownout circuit is implemented to provide the proper internal reset signal to the device during power-on
and power-off. The supply voltage supervisor (SVS) circuitry detects if the supply voltage drops below a user
selectable level and supports both supply voltage supervision (the device is automatically reset) and supply
voltage monitoring (SVM, the device is not automatically reset).
The CPU begins code execution after the brownout circuit releases the device reset. However, VCC may not
have ramped to VCC(min) at that time. The user must insure the default FLL+ settings are not changed until VCC
reaches VCC(min). If desired, the SVS circuit can be used to determine when VCC reaches VCC(min).
digital I/O
There are six 8-bit I/O ports implemented—ports P1 through P6:
D
D
D
D
All individual I/O bits are independently programmable.
Any combination of input, output, and interrupt conditions is possible.
Edge-selectable interrupt input capability for all the eight bits of ports P1 and P2.
Read/write access to port-control registers is supported by all instructions.
Basic Timer1
The Basic Timer1 has two independent 8-bit timers which can be cascaded to form a 16-bit timer/counter. Both
timers can be read and written by software. The Basic Timer1 can be used to generate periodic interrupts and
clock for the LCD module.
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LCD drive
The LCD driver generates the segment and common signals required to drive an LCD display. The LCD
controller has dedicated data memory to hold segment drive information. Common and segment signals are
generated as defined by the mode. Static, 2-MUX, 3-MUX, and 4-MUX LCDs are supported by this peripheral.
OA
The MSP430FG43x has three configurable low-current general-purpose operational amplifiers. Each OA input
and output terminal is software-selectable and offers a flexible choice of connections for various applications.
The OA op amps primarily support front-end analog signal conditioning prior to analog-to-digital conversion.
watchdog timer
The primary function of the watchdog timer (WDT) module is to perform a controlled system restart after a
software problem occurs. If the selected time interval expires, a system reset is generated. If the watchdog
function is not needed in an application, the module can be configured as an interval timer and can generate
interrupts at selected time intervals.
USART0
The MSP430FG43x has one hardware universal synchronous/asynchronous receive transmit (USART)
peripheral module that is used for serial data communication. The USART supports synchronous SPI (3 or 4
pin) and asynchronous UART communication protocols, using double-buffered transmit and receive channels.
timer_A3
Timer_A3 is a 16-bit timer/counter with three capture/compare registers. Timer_A3 can support multiple
capture/compares, PWM outputs, and interval timing. Timer_A3 also has extensive interrupt capabilities.
Interrupts may be generated from the counter on overflow conditions and from each of the capture/compare
registers.
Timer_A3 Signal Connections
Input Pin Number
PN
Device Input
Signal
Module Input
Name
62 - P1.5
TACLK
TACLK
ACLK
ACLK
SMCLK
SMCLK
62 - P1.5
TACLK
INCLK
67 - P1.0
TA0
CCI0A
66 - P1.1
TA0
CCI0B
DVSS
DVCC
GND
65 - P1.2
59 - P2.0
14
TA1
VCC
CCI1A
CAOUT (internal)
CCI1B
DVSS
DVCC
GND
TA2
VCC
CCI2A
ACLK (internal)
CCI2B
DVSS
DVCC
GND
Module
Block
Module Output
Signal
Timer
NA
PN
67 - P1.0
CCR0
TA0
65 - P1.2
ADC12 (internal)
CCR1
TA1
59 - P2.0
CCR2
VCC
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timer_B3
Timer_B3 is a 16-bit timer/counter with three capture/compare registers. Timer_B3 can support multiple
capture/compares, PWM outputs, and interval timing. Timer_B3 also has extensive interrupt capabilities.
Interrupts may be generated from the counter on overflow conditions and from each of the capture/compare
registers.
Timer_B3 Signal Connections
Input Pin Number
PN
Device Input
Signal
Module Input
Name
63 - P1.4
TBCLK
TBCLK
ACLK
ACLK
SMCLK
SMCLK
63 - P1.4
TBCLK
INCLK
58 - P2.1
TB0
CCI0A
TB0
CCI0B
DVSS
DVCC
GND
58 - P2.1
57 - P2.2
TB1
VCC
CCI1A
57 - P2.2
TB1
CCI1B
DVSS
DVCC
GND
56 - P2.3
TB2
VCC
CCI2A
56 - P2.3
TB2
CCI2B
DVSS
DVCC
GND
Module
Block
Module Output
Signal
Timer
NA
Output Pin Number
PN
58 - P2.1
ADC12 (internal)
CCR0
CCR1
TB0
57 - P2.2
ADC12 (internal)
TB1
56 - P2.3
CCR2
TB2
VCC
comparator_A
The primary function of the comparator_A module is to support precision slope analog-to-digital conversions,
battery-voltage supervision, and monitoring of external analog signals.
ADC12
The ADC12 module supports fast, 12-bit analog-to-digital conversions. The module implements a 12-bit SAR
core, sample select control, reference generator and a 16 word conversion-and-control buffer. The
conversion-and-control buffer allows up to 16 independent ADC samples to be converted and stored without
any CPU intervention.
DAC12
The DAC12 module is a 12-bit, R-ladder, voltage output DAC. The DAC12 may be used in 8- or 12-bit mode,
and may be used in conjunction with the DMA controller. When multiple DAC12 modules are present, they may
be grouped together for synchronous operation.
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peripheral file map
PERIPHERALS WITH WORD ACCESS
Watchdog
Watchdog timer control
WDTCTL
0120h
Timer_B3
Capture/compare register 2
TBCCR2
0196h
Capture/compare register 1
TBCCR1
0194h
Capture/compare register 0
TBCCR0
0192h
Timer_B register
TBR
0190h
Capture/compare control 2
TBCCTL2
0186h
Capture/compare control 1
TBCCTL1
0184h
Capture/compare control 0
TBCCTL0
0182h
Timer_B control
TBCTL
0180h
Timer_B interrupt vector
TBIV
011Eh
Capture/compare register 2
TACCR2
0176h
Capture/compare register 1
TACCR1
0174h
Capture/compare register 0
TACCR0
0172h
Timer_A register
TAR
0170h
Capture/compare control 2
TACCTL2
0166h
Capture/compare control 1
TACCTL1
0164h
Capture/compare control 0
TACCTL0
0162h
Timer_A control
TACTL
0160h
Timer_A interrupt vector
TAIV
012Eh
Flash control 3
FCTL3
012Ch
Flash control 2
FCTL2
012Ah
Flash control 1
FCTL1
0128h
DMA module control 0
DMACTL0
0122h
DMA module control 1
DMACTL1
0124h
DMA channel 0 control
DMA0CTL
01E0h
DMA channel 0 source address
DMA0SA
01E2h
DMA channel 0 destination address
DMA0DA
01E4h
DMA channel 0 transfer size
DMA0SZ
01E6h
Timer_A3
Flash
DMA
16
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peripheral file map (continued)
PERIPHERALS WITH WORD ACCESS (CONTINUED)
ADC12
Conversion memory 15
ADC12MEM15
015Eh
See also Peripherals
with Byte Access
Conversion memory 14
ADC12MEM14
015Ch
Conversion memory 13
ADC12MEM13
015Ah
Conversion memory 12
ADC12MEM12
0158h
Conversion memory 11
ADC12MEM11
0156h
Conversion memory 10
ADC12MEM10
0154h
Conversion memory 9
ADC12MEM9
0152h
Conversion memory 8
ADC12MEM8
0150h
Conversion memory 7
ADC12MEM7
014Eh
Conversion memory 6
ADC12MEM6
014Ch
Conversion memory 5
ADC12MEM5
014Ah
Conversion memory 4
ADC12MEM4
0148h
Conversion memory 3
ADC12MEM3
0146h
Conversion memory 2
ADC12MEM2
0144h
Conversion memory 1
ADC12MEM1
0142h
Conversion memory 0
ADC12MEM0
0140h
Interrupt-vector-word register
ADC12IV
01A8h
Inerrupt-enable register
ADC12IE
01A6h
Inerrupt-flag register
ADC12IFG
01A4h
Control register 1
ADC12CTL1
01A2h
Control register 0
ADC12CTL0
01A0h
DAC12_1 data
DAC12_1DAT
01CAh
DAC12_1 control
DAC12_1CTL
01C2h
DAC12_0 data
DAC12_0DAT
01C8h
DAC12_0 control
DAC12_0CTL
01C0h
DAC12
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peripheral file map (continued)
PERIPHERALS WITH BYTE ACCESS
OA2
Operational Amplifier 2 control register 1
Operational Amplifier 2 control register 0
OA2CTL1
OA2CTL0
0C5h
0C4h
OA1
Operational Amplifier 1 control register 1
Operational Amplifier 1 control register 0
OA1CTL1
OA1CTL0
0C3h
0C2h
OA0
Operational Amplifier 0 control register 1
Operational Amplifier 0 control register 0
OA0CTL1
OA0CTL0
0C1h
0C0h
LCD
LCD memory 20
:
LCD memory 16
LCD memory 15
:
LCD memory 1
LCD control and mode
LCDM20
:
LCDM16
LCDM15
:
LCDM1
LCDCTL
0A4h
:
0A0h
09Fh
:
091h
090h
ADC12
ADC memory-control register 15
(Memory control
ADC memory-control register 14
registers require byte
ADC memory-control register 13
access)
ADC memory-control register 12
ADC12MCTL15
08Fh
ADC12MCTL14
08Eh
ADC12MCTL13
08Dh
ADC12MCTL12
08Ch
ADC memory-control register 11
ADC12MCTL11
08Bh
ADC memory-control register 10
ADC12MCTL10
08Ah
ADC memory-control register 9
ADC12MCTL9
089h
ADC memory-control register 8
ADC12MCTL8
088h
ADC memory-control register 7
ADC12MCTL7
087h
ADC memory-control register 6
ADC12MCTL6
086h
ADC memory-control register 5
ADC12MCTL5
085h
ADC memory-control register 4
ADC12MCTL4
084h
ADC memory-control register 3
ADC12MCTL3
083h
ADC memory-control register 2
ADC12MCTL2
082h
ADC memory-control register 1
ADC12MCTL1
081h
ADC memory-control register 0
ADC12MCTL0
080h
U0TXBUF
077h
USART0
Transmit buffer
(UART or SPI mode) Receive buffer
Comparator_A
BrownOUT, SVS
18
U0RXBUF
076h
Baud rate
U0BR1
075h
Baud rate
U0BR0
074h
Modulation control
U0MCTL
073h
Receive control
U0RCTL
072h
Transmit control
U0TCTL
071h
USART control
U0CTL
070h
Comparator_A port disable
CAPD
05Bh
Comparator_A control 2
CACTL2
05Ah
Comparator_A control 1
CACTL1
059h
SVS control register (Reset by brownout signal)
SVSCTL
056h
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peripheral file map (continued)
PERIPHERALS WITH BYTE ACCESS (CONTINUED)
FLL+Clock
FLL+ Control 1
FLL_CTL1
054h
FLL+ Control 0
FLL_CTL0
053h
System clock frequency control
SCFQCTL
052h
System clock frequency integrator
SCFI1
051h
System clock frequency integrator
SCFI0
050h
Basic Timer1
BT counter 2
BT counter 1
BT control
BTCNT2
BTCNT1
BTCTL
047h
046h
040h
Port P6
Port P6 selection
P6SEL
037h
Port P6 direction
P6DIR
036h
Port P6 output
P6OUT
035h
Port P6 input
P6IN
034h
Port P5 selection
P5SEL
033h
Port P5 direction
P5DIR
032h
Port P5 output
P5OUT
031h
Port P5 input
P5IN
030h
Port P4 selection
P4SEL
01Fh
Port P4 direction
P4DIR
01Eh
Port P4 output
P4OUT
01Dh
Port P4 input
P4IN
01Ch
Port P3 selection
P3SEL
01Bh
Port P3 direction
P3DIR
01Ah
Port P3 output
P3OUT
019h
Port P3 input
P3IN
018h
Port P2 selection
P2SEL
02Eh
Port P2 interrupt enable
P2IE
02Dh
Port P2 interrupt-edge select
P2IES
02Ch
Port P2 interrupt flag
P2IFG
02Bh
Port P2 direction
P2DIR
02Ah
Port P2 output
P2OUT
029h
Port P2 input
P2IN
028h
Port P1 selection
P1SEL
026h
Port P1 interrupt enable
P1IE
025h
Port P1 interrupt-edge select
P1IES
024h
Port P1 interrupt flag
P1IFG
023h
Port P1 direction
P1DIR
022h
Port P1 output
P1OUT
021h
Port P1 input
P1IN
020h
SFR module enable 2
ME2
005h
SFR module enable 1
ME1
004h
SFR interrupt flag 2
IFG2
003h
SFR interrupt flag 1
IFG1
002h
SFR interrupt enable 2
IE2
001h
SFR interrupt enable 1
IE1
000h
Port P5
Port P4
Port P3
Port P2
Port P1
Special functions
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absolute maximum ratings over operating free-air temperature (unless otherwise noted)†
Voltage applied at VCC to VSS . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to 4.1 V
Voltage applied to any pin (see Note) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −0.3 V to VCC + 0.3 V
Diode current at any device terminal . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . ±2 mA
Storage temperature, Tstg: (unprogrammed device) . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . −55°C to 150°C
(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. The JTAG fuse-blow voltage, VFB, is allowed to exceed the absolute maximum rating. The voltage is applied
to the TDI/TCLK pin when blowing the JTAG fuse.
recommended operating conditions
MIN
NOM
MAX
UNITS
Supply voltage during program execution,
VCC (AVCC = DVCC1/2 = VCC)
1.8
3.6
V
Supply voltage during flash memory programming,
VCC (AVCC = DVCC1/2 = VCC)
2.7
3.6
V
Supply voltage during program execution, SVS enabled
(see Note 1), VCC (AVCC = DVCC1/2 = VCC)
2
3.6
V
Supply voltage, VSS (AVSS = DVSS1/2 = VSS)
0
0
V
−40
85
°C
Operating free-air temperature range, TA
LFXT1 crystal frequency, f(LFXT1)
(see Note 2)
LF selected,
XTS_FLL=0
Watch crystal
XT1 selected,
XTS_FLL=1
Ceramic resonator
XT1 selected,
XTS_FLL=1
Crystal
32.768
Ceramic resonator
XT2 crystal frequency, f(XT2)
Crystal
VCC = 1.8 V
VCC = 3.6 V
Processor frequency (signal MCLK), f(System)
kHz
450
8000
kHz
1000
8000
kHz
450
8000
1000
8000
DC
4.15
DC
8
kHz
MHz
NOTES: 1. The minimum operating supply voltage is defined according to the trip point where POR is going active by decreasing the supply
voltage. POR is going inactive when the supply voltage is raised above the minimum supply voltage plus the hysteresis of the SVS
circuitry.
2. In LF mode, the LFXT1 oscillator requires a watch crystal. In XT1 mode, LFXT1 accepts a ceramic resonator or a crystal.
f(System) MHz
8 MHz
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
ÎÎÎÎÎ
Supply voltage range,
MSP430FG43x, during
program execution
4.15 MHz
1.8
2.7
3
Supply Voltage − V
Supply voltage range, MSP430FG43x,
during flash memory programming
3.6
Figure 1. Frequency vs Supply Voltage, typical characteristic
20
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electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
supply current into AVCC + DVCC1/2 excluding external current
PARAMETER
TEST CONDITIONS
Active mode, (see Note 1)
f(MCLK) = f(SMCLK) = 1 MHz,
f(ACLK) = 32,768 Hz
XTS_FLL=0, SELM=(0,1)
TA = −40°C to 85°C
I(LPM0)
Low-power mode, (LPM0)
(see Note 1)
TA = −40°C to 85°C
I(LPM2)
Low-power mode, (LPM2),
f(MCLK) = f (SMCLK) = 0 MHz,
f(ACLK) = 32,768 Hz, SCG0 = 0 (see Note 2)
TA = −40°C to 85°C
I(AM)
TA = −40°C
TA = 25°C
I(LPM3)
Low-power mode, (LPM3)
f(MCLK) = f(SMCLK) = 0 MHz,
f(ACLK) = 32,768 Hz, SCG0 = 1
(see Note 2 and Note 3)
TA = 60°C
TA = 85°C
TA = −40°C
TA = 25°C
TA = 60°C
TA = 85°C
TA = −40°C
TA = 25°C
I(LPM4)
Low-power mode, (LPM4)
f(MCLK) = 0 MHz, f(SMCLK) = 0 MHz,
f(ACLK) = 0 Hz, SCG0 = 1 (see Note 2)
TA = 60°C
TA = 85°C
TA = −40°C
TA = 25°C
TA = 60°C
TA = 85°C
MIN
NOM
MAX
VCC = 2.2 V
300
370
VCC = 3 V
470
570
UNIT
A
µA
VCC = 2.2 V
VCC = 3 V
55
70
95
110
VCC = 2.2 V
11
14
VCC = 3 V
17
22
1
2.0
1.1
2.0
2
3
VCC = 2.2 V
VCC = 3 V
VCC = 2.2 V
VCC = 3 V
3.5
6
1.8
2.8
1.6
2.7
2.5
3.5
4.2
7.5
0.1
0.5
0.1
0.5
0.7
1.1
1.7
3
0.1
0.8
0.1
0.8
0.8
1.2
1.9
3.5
µA
A
µA
A
µA
A
µA
A
NOTES: 1. Timer_B is clocked by f(DCOCLK) = 1 MHz. All inputs are tied to 0 V or to VCC. Outputs do not source or sink any current.
2. All inputs are tied to 0 V or to VCC. Outputs do not source or sink any current.
3. The current consumption in LPM3 is measured with active Basic Timer1 and LCD (ACLK selected). The current consumption of the
Comparator_A and the SVS module are specified in the respective sections. The LPM3 currents are characterized with a KDS
Daishinku DT−38 (6 pF) crystal and OSCCAPx=01h.
Current consumption of active mode versus system frequency, F-version:
I(AM) = I(AM) [1 MHz] × f(System) [MHz]
Current consumption of active mode versus supply voltage, F-version:
I(AM) = I(AM) [3 V] + 175 µA/V × (VCC – 3 V)
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
21
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
SCHMITT-trigger inputs − Ports P1, P2, P3, P4, P5, and P6; RST/NMI; JTAG: TCK, TMS, TDI/TCLK, TDO/TDI
PARAMETER
TEST CONDITIONS
VIT+
Positive-going input threshold voltage
VIT−
Negative-going input threshold voltage
Vhys
Input voltage hysteresis (VIT+ − VIT−)
MIN
TYP
MAX
VCC = 2.2 V
VCC = 3 V
VCC = 2.2 V
1.1
1.55
1.5
1.98
0.4
0.9
VCC = 3 V
VCC = 2.2 V
0.9
1.3
0.3
1.1
VCC = 3 V
0.5
1
UNIT
V
V
V
inputs Px.x, TAx, TBx
PARAMETER
TEST CONDITIONS
t(int)
External interrupt timing
t(cap)
Timer_A, Timer_B capture
timing
f(TAext)
f(TBext)
f(TAint)
Port P1, P2: P1.x to P2.x, external trigger signal
for the interrupt flag, (see Note 1)
VCC
2.2 V
MIN
50
TA0, TA1, TA2
2.2 V
62
TB0, TB1, TB2
3V
50
TACLK, TBCLK, INCLK: t(H) = t(L)
Timer_A, Timer_B clock
frequency
SMCLK or ACLK signal selected
MAX
UNIT
62
3V
Timer_A, Timer_B clock
frequency externally applied
to pin
TYP
ns
ns
2.2 V
8
3V
10
2.2 V
8
MHz
MHz
f(TBint)
3V
10
NOTES: 1. The external signal sets the interrupt flag every time the minimum t(int) parameters are met. It may be set even with trigger signals
shorter than t(int).
leakage current − Ports P1, P2, P3, P4, P5, and P6 (see Note 1)
PARAMETER
Ilkg(Px.y)
Leakage
current
TEST CONDITIONS
Port Px
V(Px.y) (see Note 2)
MIN
TYP
VCC = 2.2 V/3 V
NOTES: 1. The leakage current is measured with VSS or VCC applied to the corresponding pin(s), unless otherwise noted.
2. The port pin must be selected as input.
22
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
MAX
UNIT
±50
nA
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
outputs − Ports P1, P2, P3, P4, P5, and P6
PARAMETER
VOH
VOL
High-level output voltage
Low-level output voltage
TEST CONDITIONS
MIN
IOH(max) = −1.5 mA,
IOH(max) = −6 mA,
VCC = 2.2 V,
VCC = 2.2 V,
See Note 1
IOH(max) = −1.5 mA,
IOH(max) = −6 mA,
VCC = 3 V,
VCC = 3 V,
See Note 1
IOL(max) = 1.5 mA,
IOL(max) = 6 mA,
VCC = 2.2 V,
VCC = 2.2 V,
See Note 1
IOL(max) = 1.5 mA,
IOL(max) = 6 mA,
VCC = 3 V,
VCC = 3 V,
See Note 1
See Note 2
See Note 2
TYP
MAX
VCC−0.25
VCC−0.6
VCC
VCC
VCC−0.25
VCC−0.6
VCC
VCC
VSS
VSS
VSS+0.25
VSS+0.6
VSS
VSS
VSS+0.25
VSS+0.6
See Note 2
See Note 2
UNIT
V
V
NOTES: 1. The maximum total current, IOH(max) and IOL(max), for all outputs combined, should not exceed ±12 mA to satisfy the maximum
specified voltage drop.
2. The maximum total current, IOH(max) and IOL(max), for all outputs combined, should not exceed ±48 mA to satisfy the maximum
specified voltage drop.
output frequency
PARAMETER
f(Px.y)
(1 ≤ x ≤ 6, 0 ≤ y ≤ 7)
f(MCLK)
f(SMCLK)
P1.1/TA0/MCLK,
f(ACLK)
P1.5/TACLK/ACLK
P1.4/TBCLK/SMCLK,
TEST CONDITIONS
CL = 20 pF,
IL = ±1.5 mA
Duty cycle of output frequency
TYP
DC
CL = 20 pF
P1.5/TACLK/ACLK,
CL = 20 pF
VCC = 2.2 V / 3 V
t(Xdc)
VCC = 2.2 V / 3 V
MIN
P1.1/TA0/MCLK,
CL = 20 pF,
VCC = 2.2 V / 3 V
P1.4/TBCLK/SMCLK,
CL = 20 pF,
VCC = 2.2 V / 3 V
POST OFFICE BOX 655303
f(ACLK) = f(LFXT1) = f(XT1)
f(ACLK) = f(LFXT1) = f(LF)
f(ACLK) = f(LFXT1)
f(MCLK) = f(XT1)
f(MCLK) = f(DCOCLK)
f(SMCLK) = f(XT2)
f(SMCLK) = f(DCOCLK)
• DALLAS, TEXAS 75265
40%
MAX
UNIT
fSystem
MHz
fSystem
MHz
60%
30%
70%
50%
40%
60%
50%−
15 ns
50%
50%+
15 ns
40%
60%
50%−
15 ns
50%
50%+
15 ns
23
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
outputs − Ports P1, P2, P3, P4, P5, and P6 (continued)
TYPICAL LOW-LEVEL OUTPUT CURRENT
vs
LOW-LEVEL OUTPUT VOLTAGE
TYPICAL LOW-LEVEL OUTPUT CURRENT
vs
LOW-LEVEL OUTPUT VOLTAGE
25
TA = 25°C
VCC = 2.2 V
P2.7
14
12
I OL − Typical Low-level Output Current − mA
I OL − Typical Low-level Output Current − mA
16
TA = 85°C
10
8
6
4
2
0
0.0
0.5
1.0
1.5
2.0
VCC = 3 V
P2.7
20
TA = 85°C
15
10
5
0
0.0
2.5
TA = 25°C
0.5
VOL − Low-Level Output Voltage − V
1.0
Figure 2
I OL − Typical High-level Output Current − mA
I OL − Typical High-level Output Current − mA
−6
−8
TA = 85°C
−12
TA = 25°C
0.5
3.5
1.0
1.5
2.0
2.5
VCC = 3 V
P2.7
−5
−10
−15
−20
TA = 85°C
−25
−30
0.0
VOH − High-Level Output Voltage − V
TA = 25°C
0.5
1.0
1.5
Figure 5
POST OFFICE BOX 655303
2.0
2.5
3.0
VOH − High-Level Output Voltage − V
Figure 4
24
3.0
0
VCC = 2.2 V
P2.7
−4
−14
0.0
2.5
TYPICAL HIGH-LEVEL OUTPUT CURRENT
vs
HIGH-LEVEL OUTPUT VOLTAGE
0
−10
2.0
Figure 3
TYPICAL HIGH-LEVEL OUTPUT CURRENT
vs
HIGH-LEVEL OUTPUT VOLTAGE
−2
1.5
VOL − Low-Level Output Voltage − V
• DALLAS, TEXAS 75265
3.5
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
wake-up LPM3
PARAMETER
TEST CONDITIONS
MIN
TYP
MAX
f = 1 MHz
td(LPM3)
f = 2 MHz
Delay time
UNIT
6
6
VCC = 2.2 V/3 V
f = 3 MHz
µs
6
RAM
PARAMETER
TEST CONDITIONS
VRAMh
MIN
CPU halted (see Note 1)
TYP
MAX
1.6
UNIT
V
NOTE 1: This parameter defines the minimum supply voltage when the data in program memory RAM remain unchanged. No program execution
should take place during this supply voltage condition.
LCD
PARAMETER
V(33)
V(23)
V(13)
V(33) − V(03)
2.5
Voltage at P5.5/R13
R03 = VSS
Input leakage
P5.5/R13 = VCC/3
P5.6/R23 = 2 × VCC/3
Segment line
voltage
I(Sxx) = −3 µA,
2.5
No load at all
segment and
common lines,
VCC = 3 V
VCC = 3 V
V(Sxx3)
POST OFFICE BOX 655303
TYP
MAX
UNIT
VCC + 0.2
[V(33)−V(03)] × 2/3 + V(03)
[V(33)−V(03)] × 1/3 + V(03)
VCC = 3 V
Voltage at R33 to R03
I(R23)
V(Sxx0)
V(Sxx1)
V(Sxx2)
MIN
Voltage at P5.6/R23
Analog voltage
I(R03)
I(R13)
TEST CONDITIONS
Voltage at P5.7/R33
V
VCC + 0.2
±20
±20
nA
±20
V(03)
V(13)
V(03) − 0.1
V(13) − 0.1
V(23)
V(33)
V(23) − 0.1
V(33) + 0.1
• DALLAS, TEXAS 75265
V
25
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
Comparator_A (see Note 1)
PARAMETER
TEST CONDITIONS
I(CC)
CAON=1, CARSEL=0, CAREF=0
I(Refladder/RefDiode)
CAON=1, CARSEL=0, CAREF=1/2/3,
No load at P1.6/CA0 and
P1.7/CA1
V(Ref025)
Voltage @ 0.25 V
V(Ref050)
V
CC
TYP
MAX
VCC = 2.2 V
VCC = 3 V
25
40
45
60
VCC = 2.2 V
30
50
VCC = 3 V
45
71
node
PCA0=1, CARSEL=1, CAREF=1,
No load at P1.6/CA0 and P1.7/CA1
VCC = 2.2 V / 3 V
0.23
0.24
0.25
node
PCA0=1, CARSEL=1, CAREF=2,
No load at P1.6/CA0 and P1.7/CA1
VCC = 2.2V / 3 V
0.47
0.48
0.5
PCA0=1, CARSEL=1, CAREF=3,
No load at P1.6/CA0 and P1.7/CA1;
TA = 85°C
VCC = 2.2 V
390
480
540
VCC = 3 V
400
490
550
CC
V
CC
Voltage @ 0.5 V
MIN
CC
UNIT
µA
A
µA
A
V(RefVT)
see Figure 6 and Figure 7
VIC
Common-mode input
voltage range
CAON=1
VCC = 2.2 V / 3 V
0
VCC−1
Offset voltage
See Note 2
VCC = 2.2 V / 3 V
−30
30
mV
Input hysteresis
CAON = 1
VCC = 2.2 V / 3 V
VCC = 2.2 V
0
0.7
1.4
mV
160
210
300
80
150
240
1.4
1.9
3.4
0.9
1.5
2.6
130
210
300
80
150
240
1.4
1.9
3.4
Vp−VS
Vhys
TA = 25
25°C,
C,
Overdrive 10 mV, without filter: CAF = 0
t(response LH)
TA = 25
25°C
C
Overdrive 10 mV, with filter: CAF = 1
TA = 25
25°C
C
Overdrive 10 mV, without filter: CAF = 0
t(response HL)
25°C,
TA = 25
C,
Overdrive 10 mV, with filter: CAF = 1
mV
VCC = 3 V
VCC = 2.2 V
VCC = 3 V
VCC = 2.2 V
VCC = 3 V
VCC = 2.2 V
V
ns
µss
ns
µss
VCC = 3 V
0.9
1.5
2.6
NOTES: 1. The leakage current for the Comparator_A terminals is identical to Ilkg(Px.x) specification.
2. The input offset voltage can be cancelled by using the CAEX bit to invert the Comparator_A inputs on successive measurements.
The two successive measurements are then summed together.
26
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
typical characteristics
REFERENCE VOLTAGE
vs
FREE-AIR TEMPERATURE
REFERENCE VOLTAGE
vs
FREE-AIR TEMPERATURE
650
650
VCC = 3 V
VCC = 2.2 V
VREF − Reference Voltage − V
VREF − Reference Voltage − V
600
Typical
550
500
450
400
−45
−25
−5
15
35
55
75
600
Typical
550
500
450
400
−45
95
−25
TA − Free-Air Temperature − °C
−5
15
35
55
75
95
TA − Free-Air Temperature − °C
Figure 6. V(RefVT) vs Temperature
Figure 7. V(RefVT) vs Temperature
0 V VCC
0
1
CAF
CAON
Low-Pass Filter
V+
V−
+
_
0
0
1
1
To Internal
Modules
CAOUT
Set CAIFG
Flag
τ ≈ 2 µs
Figure 8. Block Diagram of Comparator_A Module
VCAOUT
Overdrive
V−
400 mV
V+
t(response)
Figure 9. Overdrive Definition
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
27
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
POR/brownout reset (BOR) (see Note 1)
PARAMETER
TEST CONDITIONS
td(BOR)
VCC(start)
MIN
dVCC/dt ≤ 3 V/s (see Figure 10)
V(B_IT−)
Vhys(B_IT−)
MAX
UNIT
2000
µs
0.7 × V(B_IT−)
dVCC/dt ≤ 3 V/s (see Figure 10 through Figure 12)
dVCC/dt ≤ 3 V/s (see Figure 10)
Brownout
(see Note 2)
TYP
70
130
V
1.71
V
180
mV
Pulse length needed at RST/NMI pin to accepted reset internally,
2
µs
VCC = 2.2 V/3 V
NOTES: 1. The current consumption of the brownout module is already included in the ICC current consumption data. The voltage level V(B_IT−)
+ Vhys(B_IT−) is ≤ 1.8V.
2. During power up, the CPU begins code execution following a period of td(BOR) after VCC = V(B_IT−) + Vhys(B_IT−). The default
FLL+ settings must not be changed until VCC ≥ VCC(min), where VCC(min) is the minimum supply voltage for the desired
operating frequency. See the MSP430x4xx Family User’s Guide (SLAU056) for more information on the brownout/SVS circuit.
t(reset)
typical characteristics
VCC
Vhys(B_IT−)
V(B_IT−)
VCC(start)
1
0
t d(BOR)
Figure 10. POR/Brownout Reset (BOR) vs Supply Voltage
VCC
3V
2
VCC(min)− V
VCC = 3 V
Typical Conditions
t pw
1.5
1
VCC(min)
0.5
0
0.001
1
1000
1 ns
tpw − Pulse Width − µs
1 ns
tpw − Pulse Width − µs
Figure 11. V(CC)min Level With a Square Voltage Drop to Generate a POR/Brownout Signal
28
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
typical characteristics
VCC
VCC(min)− V
2
1.5
t pw
3V
VCC = 3 V
Typical Conditions
1
VCC(min)
0.5
0
0.001
tf = tr
1
1000
tf
tr
tpw − Pulse Width − µs
tpw − Pulse Width − µs
Figure 12. VCC(min) Level With a Triangle Voltage Drop to Generate a POR/Brownout Signal
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
SVS (supply voltage supervisor/monitor)
PARAMETER
TEST CONDITIONS
MIN
t(SVSR)
dVCC/dt > 30 V/ms (see Figure 13)
dVCC/dt ≤ 30 V/ms
5
td(SVSon)
tsettle
SVSon, switch from VLD=0 to VLD ≠ 0, VCC = 3 V
VLD ≠ 0‡
20
V(SVSstart)
VLD ≠ 0, VCC/dt ≤ 3 V/s (see Figure 13)
NOM
1.55
VLD = 1
VCC/dt ≤ 3 V/s (see Figure 13)
VLD = 2 .. 14
Vhys(SVS_IT−)
VCC/dt ≤ 3 V/s (see Figure 13), external voltage applied
on A7
VCC/dt ≤ 3 V/s (see Figure 13)
V(SVS_IT−)
VCC/dt ≤ 3 V/s (see Figure 13), external voltage applied
on A7
VLD = 15
70
120
V(SVS_IT−)
x 0.001
MAX
UNIT
150
µs
2000
µs
150
µs
12
µs
1.7
V
155
mV
V(SVS_IT−)
x 0.016
4.4
20
VLD = 1
1.8
1.9
2.05
VLD = 2
1.94
2.1
2.23
VLD = 3
2.05
2.2
2.35
VLD = 4
2.14
2.3
2.46
VLD = 5
2.24
2.4
2.58
VLD = 6
2.33
2.5
2.69
VLD = 7
2.46
2.65
2.84
VLD = 8
2.58
2.8
2.97
VLD = 9
2.69
2.9
3.10
VLD = 10
2.83
3.05
3.26
VLD = 11
2.94
3.2
VLD = 12
3.11
3.35
VLD = 13
3.24
VLD = 14
3.43
3.5
3.7†
3.39
3.58†
3.73†
VLD = 15
1.1
1.2
mV
V
3.96†
1.3
ICC(SVS)
VLD ≠ 0, VCC = 2.2 V/3 V
10
15
µA
(see Note 1)
† The recommended operating voltage range is limited to 3.6 V.
‡ tsettle is the settling time that the comparator o/p needs to have a stable level after VLD is switched VLD ≠ 0 to a different VLD value somewhere
between 2 and 15. The overdrive is assumed to be > 50 mV.
NOTE 1: The current consumption of the SVS module is not included in the ICC current consumption data.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
29
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
typical characteristics
Software Sets VLD>0:
SVS is Active
VCC
V(SVS_IT−)
V(SVSstart)
Vhys(SVS_IT−)
Vhys(B_IT−)
V(B_IT−)
VCC(start)
BrownOut
Region
Brownout
Region
Brownout
1
0
SVSOut
1
td(BOR)
t d(BOR)
SVS Circuit is Active From VLD > to VCC < V(B_IT−)
0
td(SVSon)
Set POR
1
td(SVSR)
undefined
0
Figure 13. SVS Reset (SVSR) vs Supply Voltage
VCC
3V
t pw
2
Rectangular Drop
VCC(min)
VCC(min)− V
1.5
Triangular Drop
1
1 ns
1 ns
0.5
VCC
t pw
3V
0
1
10
100
1000
tpw − Pulse Width − µs
VCC(min)
tf = tr
tf
tr
t − Pulse Width − µs
Figure 14. VCC(min) With a Square Voltage Drop and a Triangle Voltage Drop to Generate an SVS Signal
30
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
DCO
PARAMETER
f(DCOCLK)
TEST CONDITIONS
VCC
2.2 V/3 V
MIN
TYP
2.2 V
0.3
0.65
1.25
3V
0.3
0.7
1.3
2.2 V
2.5
5.6
10.5
3V
2.7
6.1
11.3
2.2 V
0.7
1.3
2.3
3V
0.8
1.5
2.5
2.2 V
5.7
10.8
18
3V
6.5
12.1
20
2.2 V
1.2
2
3
3V
1.3
2.2
3.5
2.2 V
9
15.5
25
3V
10.3
17.9
28.5
2.2 V
1.8
2.8
4.2
3V
2.1
3.4
5.2
2.2 V
13.5
21.5
33
3V
16
26.6
41
2.2 V
2.8
4.2
6.2
3V
4.2
6.3
9.2
2.2 V
21
32
46
3V
30
46
70
1 < TAP ≤ 20
1.06
TAP = 27
1.07
2.2 V
–0.2
–0.3
–0.4
3V
–0.2
–0.3
–0.4
2.2 V/ 3 V
0
5
15
N(DCO)=01E0h, FN_8=FN_4=FN_3=FN_2=0, D = 2; DCOPLUS= 0
f(DCO2)
FN_8=FN_4=FN_3=FN_2=0 ; DCOPLUS = 1
f(DCO27)
FN_8=FN_4=FN_3=FN_2=0; DCOPLUS = 1, (see Note 1)
f(DCO2)
FN_8=FN_4=FN_3=0, FN_2=1; DCOPLUS = 1
f(DCO27)
FN_8=FN_4=FN_3=0, FN_2=1; DCOPLUS = 1, (see Note 1)
f(DCO2)
FN_8=FN_4=0, FN_3= 1, FN_2=x; DCOPLUS = 1
f(DCO27)
FN_8=FN_4=0, FN_3= 1, FN_2=x; DCOPLUS = 1, (see Note 1)
f(DCO2)
FN_8=0, FN_4= 1, FN_3= FN_2=x; DCOPLUS = 1
f(DCO27)
FN_8=0, FN_4=1, FN_3= FN_2=x; DCOPLUS = 1, (see Note 1)
f(DCO2)
FN_8=1, FN_4=FN_3=FN_2=x; DCOPLUS = 1
f(DCO27)
FN_8=1,FN_4=FN_3=FN_2=x; DCOPLUS = 1, (see Note 1)
Sn
Step size between adjacent DCO taps:
Sn = fDCO(Tap n+1) / fDCO(Tap n), (see Figure 16 for taps 21 to 27)
Dt
Temperature drift, N(DCO) = 01E0h, FN_8=FN_4=FN_3=FN_2=0
D = 2; DCOPLUS = 0, (see Note 2)
DV
Drift with VCC variation, N(DCO) = 01E0h, FN_8=FN_4=FN_3=FN_2=0
D = 2; DCOPLUS = 0 (see Note 2)
MAX
1
UNIT
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
MHz
1.11
1.17
%/_C
%/V
NOTES: 1. Do not exceed the maximum system frequency.
2. This parameter is not production tested.
f
f
f
(DCO)
f
(DCO3V)
(DCO)
(DCO205C)
1.0
1.0
0
1.8
2.4
3.0
3.6
VCC − V
−40
−20
0
20
40
60
85
TA − °C
Figure 15. DCO Frequency vs Supply Voltage VCC and vs Ambient Temperature
POST OFFICE BOX 655303
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31
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
Sn - Stepsize Ratio between DCO Taps
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
1.17
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
ÎÎÎÎÎÎÎÎÎÎÎÎÎ
Max
1.11
1.07
1.06
Min
1
20
27
DCO Tap
Figure 16. DCO Tap Step Size
f(DCO)
Legend
Tolerance at Tap 27
DCO Frequency
Adjusted by Bits
29 to 25 in SCFI1 {N{DCO}}
Tolerance at Tap 2
Overlapping DCO Ranges:
Uninterrupted Frequency Range
FN_2=0
FN_3=0
FN_4=0
FN_8=0
FN_2=1
FN_3=0
FN_4=0
FN_8=0
FN_2=x
FN_3=1
FN_4=0
FN_8=0
FN_2=x
FN_3=x
FN_4=1
FN_8=0
FN_2=x
FN_3=x
FN_4=x
FN_8=1
Figure 17. Five Overlapping DCO Ranges Controlled by FN_x Bits
32
POST OFFICE BOX 655303
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SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
crystal oscillator, LFXT1 oscillator (see Notes 1 and 2)
PARAMETER
CXIN
CXOUT
Integrated input capacitance
(see Note 4)
Integrated output capacitance
(see Note 4)
TEST CONDITIONS
MIN
TYP
OSCCAPx = 0h, VCC = 2.2 V / 3 V
0
OSCCAPx = 1h, VCC = 2.2 V / 3 V
10
OSCCAPx = 2h, VCC = 2.2 V / 3 V
14
OSCCAPx = 3h, VCC = 2.2 V / 3 V
18
OSCCAPx = 0h, VCC = 2.2 V / 3 V
0
OSCCAPx = 1h, VCC = 2.2 V / 3 V
10
OSCCAPx = 2h, VCC = 2.2 V / 3 V
14
OSCCAPx = 3h, VCC = 2.2 V / 3 V
VIL
VIH
Input levels at XIN
VCC = 2.2 V/3 V (see Note 3)
MAX
UNIT
pF
pF
18
VSS
0.8×VCC
0.2×VCC
VCC
V
NOTES: 1. The parasitic capacitance from the package and board may be estimated to be 2 pF. The effective load capacitor for the crystal is
(CXIN x CXOUT) / (CXIN + CXOUT). This is independent of XTS_FLL.
2. To improve EMI on the low-power LFXT1 oscillator, particularly in the LF mode (32 kHz), the following guidelines should be observed.
− Keep as short of a trace as possible between the ’FG43x and the crystal.
− Design a good ground plane around the oscillator pins.
− Prevent crosstalk from other clock or data lines into oscillator pins XIN and XOUT.
− Avoid running PCB traces underneath or adjacent to the XIN and XOUT pins.
− Use assembly materials and praxis to avoid any parasitic load on the oscillator XIN and XOUT pins.
− If conformal coating is used, ensure that it does not induce capacitive/resistive leakage between the oscillator pins.
− Do not route the XOUT line to the JTAG header to support the serial programming adapter as shown in other
documentation. This signal is no longer required for the serial programming adapter.
3. Applies only when using an external logic-level clock source. XTS_FLL must be set. Not applicable when using a crystal or resonator.
4. External capacitance is recommended for precision real-time clock applications; OSCCAPx = 0h.
crystal oscillator, XT2 oscillator (see Note 1)
PARAMETER
CXT2IN
Integrated input capacitance
CXT2OUT
Integrated output capacitance
VIL
VIH
Input levels at XT2IN
TEST CONDITIONS
MIN
NOM
VCC = 2.2 V/3 V
VCC = 2.2 V/3 V
MAX
2
pF
2
VCC = 2.2 V/3 V (see Note 2)
VSS
0.8 × VCC
UNIT
pF
0.2 × VCC
V
VCC
V
NOTES: 1. The oscillator needs capacitors at both terminals, with values specified by the crystal manufacturer.
2. Applies only when using an external logic-level clock source. Not applicable when using a crystal or resonator.
USART0 (see Note 1)
PARAMETER
t(τ)
( )
USART0: deglitch time
TEST CONDITIONS
VCC = 2.2 V
VCC = 3 V
MIN
NOM
MAX
200
430
800
150
280
500
UNIT
ns
NOTES: 1. The signal applied to the USART0 receive signal/terminal (URXD0) 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 URXD0 line.
POST OFFICE BOX 655303
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33
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit ADC, power supply and input range conditions (see Note 1)
PARAMETER
TEST CONDITIONS
MIN
AVCC
Analog supply voltage
AVCC and DVCC are connected together
AVSS and DVSS are connected together
V(AVSS) = V(DVSS) = 0 V
V(P6.x/Ax)
Analog input voltage
range (see Note 2)
All external Ax terminals. Analog inputs
selected in ADC12MCTLx register and P6Sel.x=1
V(AVSS) ≤ VAx ≤ V(AVCC)
IADC12
Operating supply current
into AVCC terminal
(see Note 3)
fADC12CLK = 5.0 MHz
ADC12ON = 1, REFON = 0
SHT0=0, SHT1=0, ADC12DIV=0
Operating supply current
into AVCC terminal
(see Note 4)
IREF+
CI †
Input capacitance
NOM
MAX
UNIT
2.2
3.6
V
0
VAVCC
V
VCC = 2.2 V
0.65
1.3
VCC = 3 V
0.8
1.6
VCC = 3 V
0.5
0.8
VCC = 2.2 V
0.5
0.8
VCC = 3 V
0.5
0.8
mA
fADC12CLK = 5.0 MHz
ADC12ON = 0,
REFON = 1, REF2_5V = 1
fADC12CLK = 5.0 MHz
ADC12ON = 0,
REFON = 1, REF2_5V = 0
mA
mA
Only one terminal can be selected
at one time, Ax
VCC = 2.2 V
40
pF
RI†
Input MUX ON resistance 0V ≤ VAx ≤ VAVCC
VCC = 3 V
2000
Ω
† Not production tested, limits verified by design
NOTES: 1. The leakage current is defined in the leakage current table with Ax parameter.
2. The analog input voltage range must be within the selected reference voltage range VR+ to VR− for valid conversion results.
3. The internal reference supply current is not included in current consumption parameter IADC12.
4. The internal reference current is supplied via terminal AVCC. Consumption is independent of the ADC12ON control bit, unless a
conversion is active. The REFON bit enables to settle the built-in reference before starting an A/D conversion.
12-bit ADC, external reference (see Note 1)
PARAMETER
TEST CONDITIONS
MIN
NOM
MAX
UNIT
VeREF+
Positive external
reference voltage input
VeREF+ > VREF−/VeREF−
(see Note 2)
1.4
VAVCC
V
VREF− /VeREF−
Negative external
reference voltage input
VeREF+ > VREF−/VeREF−
(see Note 3)
0
1.2
V
(VeREF+ −
VREF−/VeREF−)
Differential external
reference voltage input
VeREF+ > VREF−/VeREF−
(see Note 4)
1.4
VAVCC
V
IVeREF+
IVREF−/VeREF−
Static input current
0V ≤VeREF+ ≤ VAVCC
±1
µA
VCC = 2.2 V/3 V
VCC = 2.2 V/3 V
Static input current
0V ≤ VeREF− ≤ VAVCC
±1
µA
NOTES: 1. The external reference is used during conversion to charge and discharge the capacitance array. The input capacitance, CI, is also
the dynamic load for an external reference during conversion. The dynamic impedance of the reference supply should follow the
recommendations on analog-source impedance to allow the charge to settle for 12-bit accuracy.
2. The accuracy limits the minimum positive external reference voltage. Lower reference voltage levels may be applied with reduced
accuracy requirements.
3. The accuracy limits the maximum negative external reference voltage. Higher reference voltage levels may be applied with reduced
accuracy requirements.
4. The accuracy limits minimum external differential reference voltage. Lower differential reference voltage levels may be applied with
reduced accuracy requirements.
34
POST OFFICE BOX 655303
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SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit ADC, built-in reference
PARAMETER
Positive built-in reference
voltage output
VREF+
AVCC(min)
AVCC minimum voltage,
Positive built-in reference
active
IVREF+
Load current out of VREF+
terminal
Load-current regulation
VREF+ terminal
IL(VREF)+ †
TEST CONDITIONS
REF2_5V = 1 for 2.5 V
IVREF+max ≤ IVREF+≤ IVREF+min
VCC = 3 V
REF2_5V = 0 for 1.5 V
IVREF+max ≤ IVREF+≤ IVREF+min
VCC =
2.2 V/3 V
MIN
NOM
MAX
2.4
2.5
2.6
1.44
1.5
1.56
V
REF2_5V = 0, IVREF+max ≤ IVREF+≤ IVREF+min
2.2
REF2_5V = 1, IVREF+min ≥ IVREF+≥ −0.5mA
2.8
REF2_5V = 1, IVREF+min ≥ IVREF+≥ −1mA
V
2.9
VCC = 2.2 V
VCC = 3 V
IVREF+ = 500 µA +/− 100 µA
Analog input voltage ~0.75 V;
REF2_5V = 0
UNIT
0.01
−0.5
0.01
−1
mA
VCC = 2.2 V
±2
VCC = 3 V
±2
IVREF+ = 500 µA ± 100 µA
Analog input voltage ~1.25 V;
REF2_5V = 1
VCC = 3 V
±2
LSB
20
ns
IDL(VREF) +‡
Load current regulation
VREF+ terminal
IVREF+ =100 µA → 900 µA,
CVREF+=5 µF, ax ~0.5 x VREF+
Error of conversion result ≤ 1 LSB
VCC = 3 V
CVREF+
Capacitance at pin VREF+
(see Note 1)
REFON =1,
0 mA ≤ IVREF+ ≤ IVREF+max
VCC =
2.2 V/3 V
TREF+†
Temperature coefficient of
built-in reference
IVREF+ is a constant in the range of
0 mA ≤ IVREF+ ≤ 1 mA
VCC =
2.2 V/3 V
tREFON†
Settle time of internal
reference voltage (see
Figure 18 and Note 2)
IVREF+ = 0.5 mA, CVREF+ = 10 µF,
VREF+ = 1.5 V, VAVCC = 2.2 V
5
LSB
µF
10
±100
ppm/°C
17
ms
† Not production tested, limits characterized
‡ Not production tested, limits verified by design
NOTES: 1. The internal buffer operational amplifier and the accuracy specifications require an external capacitor. All INL and DNL tests uses
two capacitors between pins VREF+ and AVSS and VREF−/VeREF− and AVSS: 10 µF tantalum and 100 nF ceramic.
2. The condition is that the error in a conversion started after tREFON is less than ±0.5 LSB. The settling time depends on the external
capacitive load.
CVREF+
100 µF
tREFON ≈ .66 x CVREF+ [ms] with CVREF+ in µF
10 µF
1 µF
0
1 ms
10 ms
100 ms
tREFON
Figure 18. Typical Settling Time of Internal Reference tREFON vs External Capacitor on VREF+
POST OFFICE BOX 655303
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35
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
DVCC1/2
From
Power
Supply
+
−
10 µ F
DVSS1/2
100 nF
AVCC
+
−
10 µ F
Apply External Reference [VeREF+]
or Use Internal Reference [VREF+]
100 nF
VREF+ or VeREF+
+
−
Apply
External
Reference
10 µ F
100 nF
VREF−/VeREF−
+
−
10 µ F
MSP430FG43x
AVSS
100 nF
Figure 19. Supply Voltage and Reference Voltage Design VREF−/VeREF− External Supply
From
Power
Supply
DVCC1/2
+
−
10 µ F
DVSS1/2
100 nF
AVCC
+
−
Apply External Reference [VeREF+]
or Use Internal Reference [VREF+]
10 µ F
100 nF
VREF+ or VeREF+
+
−
10 µ F
MSP430FG43x
AVSS
100 nF
Reference Is Internally
Switched to AVSS
VREF−/VeREF−
Figure 20. Supply Voltage and Reference Voltage Design VREF−/VeREF− = AVSS, Internally Connected
36
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit ADC, timing parameters
PARAMETER
TEST CONDITIONS
fADC12CLK
fADC12OSC
Internal ADC12
oscillator
MIN
NOM
MAX
UNIT
For specified performance of
ADC12 linearity parameters
VCC =
2.2V/3 V
0.45
5
6.3
MHz
ADC12DIV=0,
fADC12CLK=fADC12OSC
VCC =
2.2 V/ 3 V
3.7
5
6.3
MHz
CVREF+ ≥ 5 µF, Internal oscillator,
fADC12OSC = 3.7 MHz to 6.3 MHz
VCC =
2.2 V/ 3 V
2.06
3.51
µs
tCONVERT
Conversion time
tADC12ON‡
Turn on settling time of
the ADC
(see Note 1)
tSample‡
Sampling time
RS = 400 Ω, RI = 1000 Ω,
CI = 30 pF, τ = [RS + RI] x CI
(see Note 2)
External fADC12CLK from ACLK, MCLK or SMCLK:
ADC12SSEL ≠ 0
13×ADC12DIV×
1/fADC12CLK
µs
100
VCC = 3 V
VCC =
2.2 V
ns
1220
ns
1400
† Not production tested, limits characterized
‡ Not production tested, limits verified by design
NOTES: 1. The condition is that the error in a conversion started after tADC12ON is less than ±0.5 LSB. The reference and input signal are already
settled.
2. Approximately ten Tau (τ) are needed to get an error of less than ±0.5 LSB:
tSample = ln(2n+1) x (RS + RI) x CI+ 800 ns where n = ADC resolution = 12, RS = external source resistance.
12-bit ADC, linearity parameters
PARAMETER
EI
Integral linearity error
ED
Differential linearity
error
EO
Offset error
EG
Gain error
ET
Total unadjusted
error
TEST CONDITIONS
1.4 V ≤ (VeREF+ − VREF−/VeREF−) min ≤ 1.6 V
1.6 V < (VeREF+ − VREF−/VeREF−) min ≤ [VAVCC]
(VeREF+ − VREF−/VeREF−)min ≤ (VeREF+ − VREF−/VeREF−),
CVREF+ = 10 µF (tantalum) and 100 nF (ceramic)
(VeREF+ − VREF−/VeREF−)min ≤ (VeREF+ − VREF−/VeREF−),
Internal impedance of source RS < 100 Ω,
CVREF+ = 10 µF (tantalum) and 100 nF (ceramic)
(VeREF+ − VREF−/VeREF−)min ≤ (VeREF+ − VREF−/VeREF−),
CVREF+ = 10 µF (tantalum) and 100 nF (ceramic)
(VeREF+ − VREF−/VeREF−)min ≤ (VeREF+ − VREF−/VeREF−),
CVREF+ = 10 µF (tantalum) and 100 nF (ceramic)
POST OFFICE BOX 655303
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MIN
NOM
MAX
±2
UNIT
VCC =
2.2 V/3 V
±1.7
LSB
VCC =
2.2 V/3 V
±1
LSB
VCC =
2.2 V/3 V
±2
±4
LSB
VCC =
2.2 V/3 V
±1.1
±2
LSB
VCC =
2.2 V/3 V
±2
±5
LSB
37
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit ADC, temperature sensor and built-in VMID
PARAMETER
TEST CONDITIONS
VCC
2.2 V
MIN
NOM
MAX
40
120
60
160
ISENSOR
Operating supply current into
AVCC terminal (see Note 1)
REFON = 0, INCH = 0Ah,
ADC12ON=NA, TA = 25_C
VSENSOR†
(see Note 2)
ADC12ON = 1, INCH = 0Ah,
TA = 0°C
2.2 V/
3V
986
ADC12ON = 1, INCH = 0Ah
2.2 V/
3V
3.55±3%
TCSENSOR†
3V
mV/°C
Sample time required if
channel 10 is selected
(see Note 3)
ADC12ON = 1, INCH = 0Ah,
Error of conversion result ≤ 1 LSB
IVMID
Current into divider at
channel 11 (see Note 4)
ADC12ON = 1, INCH = 0Bh,
1.1
1.1±0.04
AVCC divider at channel 11
ADC12ON = 1, INCH = 0Bh,
VMID is ~0.5 x VAVCC
2.2 V
VMID
3V
1.5
1.50±0.04
Sample time required if
channel 11 is selected
(see Note 5)
ADC12ON = 1, INCH = 0Bh,
Error of conversion result ≤ 1 LSB
2.2 V
1400
tVMID(sample)
3V
1220
30
3V
30
µA
A
mV
tSENSOR(sample)†
2.2 V
UNIT
µss
2.2 V
NA
3V
NA
µA
A
V
ns
† Not production tested, limits characterized
NOTES: 1. The sensor current ISENSOR is consumed if (ADC12ON = 1 and REFON=1), or (ADC12ON=1 AND INCH=0Ah and sample signal
is high). When REFON = 1, ISENSOR is already included in IREF+.
2. The temperature sensor offset can be as much as ±20_C. A single-point calibration is recommended in order to minimize the offset
error of the built-in temperature sensor.
3. The typical equivalent impedance of the sensor is 51 kΩ. The sample time required includes the sensor-on time tSENSOR(on)
4. No additional current is needed. The VMID is used during sampling.
5. The on-time tVMID(on) is included in the sampling time tVMID(sample); no additional on time is needed.
12-bit DAC, supply specifications
PARAMETER
AVCC
IDD
PSRR
Analog supply voltage
Supply Current:
Single DAC Channel
(see Notes 1 and 2)
Power supply
rejection ratio
(see Notes 3 and 4)
TEST CONDITIONS
VCC
AVCC = DVCC,
AVSS = DVSS =0 V
MIN
TYP
2.20
MAX
UNIT
3.60
V
DAC12AMPx=2, DAC12IR=0,
DAC12_xDAT=0800h
2.2V/3V
50
110
DAC12AMPx=2, DAC12IR=1,
DAC12_xDAT=0800h , VeREF+=VREF+= AVCC
2.2V/3V
50
110
DAC12AMPx=5, DAC12IR=1,
DAC12_xDAT=0800h, VeREF+=VREF+= AVCC
2.2V/3V
200
440
DAC12AMPx=7, DAC12IR=1,
DAC12_xDAT=0800h, VeREF+=VREF+= AVCC
2.2V/3V
700
1500
DAC12_xDAT = 800h, VREF = 1.5 V
∆AVCC = 100mV
DAC12_xDAT = 800h, VREF = 1.5 V or 2.5 V
∆AVCC = 100mV
µA
A
2.2V
70
dB
3V
NOTES: 1. No load at the output pin, DAC12_0 or DAC12_1, assuming that the control bits for the shared pins are set properly.
2. Current into reference terminals not included. If DAC12IR = 1 current flows through the input divider; see Reference Input
specifications.
3. PSRR = 20*log{∆AVCC/∆VDAC12_xOUT}.
4. VREF is applied externally. The internal reference is not used.
38
POST OFFICE BOX 655303
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SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit DAC, linearity specifications (see Figure 21)
PARAMETER
TEST CONDITIONS
Resolution
Differential nonlinearity
(see Note 1)
DNL
Offset voltage w/o
calibration
(see Notes 1, 2)
EO
MIN
(12-bit Monotonic)
Integral nonlinearity
(see Note 1)
INL
VCC
Offset voltage with
calibration
(see Notes 1, 2)
dE(O)/dT
Offset error
temperature coefficient
(see Note 1)
EG
Gain error (see Note 1)
dE(G)/dT
Gain temperature
coefficient (see Note 1)
tOffset_Cal
Time for offset calibration
(see Note 3)
TYP
MAX
12
Vref = 1.5 V
DAC12AMPx = 7, DAC12IR = 1
2.2V
Vref = 2.5 V
DAC12AMPx = 7, DAC12IR = 1
3V
Vref = 1.5 V
DAC12AMPx = 7, DAC12IR = 1
2.2V
Vref = 2.5 V
DAC12AMPx = 7, DAC12IR = 1
3V
Vref = 1.5 V
DAC12AMPx = 7, DAC12IR = 1
2.2V
Vref = 2.5 V
DAC12AMPx = 7, DAC12IR = 1
3V
Vref = 1.5 V
DAC12AMPx = 7, DAC12IR = 1
2.2V
Vref = 2.5 V
DAC12AMPx = 7, DAC12IR = 1
3V
UNIT
bits
±2.0
±8.0
LSB
±0.4
±1.0
LSB
±21
mV
±2.5
±30
2.2V/3V
VREF = 1.5 V
VREF = 2.5 V
2.2V
µV/C
±3.50
3V
2.2V/3V
% FSR
ppm of
FSR/°C
10
DAC12AMPx=2
2.2V/3V
100
DAC12AMPx=3,5
2.2V/3V
32
DAC12AMPx=4,6,7
2.2V/3V
6
ms
NOTES: 1. Parameters calculated from the best-fit curve from 0x0A to 0xFFF. The best-fit curve method is used to deliver coefficients “a” and
“b” of the first order equation: y = a + b*x. VDAC12_xOUT = EO + (1 + EG) * (VeREF+/4095) * DAC12_xDAT, DAC12IR = 1.
2. The offset calibration works on the output operational amplifier. Offset Calibration is triggered setting bit DAC12CALON
3. The offset calibration can be done if DAC12AMPx = {2, 3, 4, 5, 6, 7}. The output operational amplifier is switched off with DAC12AMPx
={0, 1}. It is recommended that the DAC12 module be configured prior to initiating calibration. Port activity during calibration may
effect accuracy and is not recommended.
DAC V OUT
DAC Output
VR+
RLoad =
Ideal transfer
function
AV CC
2
Offset Error
Positive
CLoad = 100pF
Negative
Gain Error
DAC Code
Figure 21. Linearity Test Load Conditions and Gain/Offset Definition
POST OFFICE BOX 655303
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39
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit DAC, linearity specifications (continued)
TYPICAL INL ERROR
vs
DIGITAL INPUT DATA
INL − Integral Nonlinearity Error − LSB
4
VCC = 2.2 V, VREF = 1.5V
DAC12AMPx = 7
DAC12IR = 1
3
2
1
0
−1
−2
−3
−4
0
512
1024
1536
2048
2560
3072
3584
4095
DAC12_xDAT − Digital Code
TYPICAL DNL ERROR
vs
DIGITAL INPUT DATA
DNL − Differential Nonlinearity Error − LSB
2.0
VCC = 2.2 V, VREF = 1.5V
DAC12AMPx = 7
DAC12IR = 1
1.5
1.0
0.5
0.0
−0.5
−1.0
−1.5
−2.0
0
512
1024
1536
2048
2560
DAC12_xDAT − Digital Code
40
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
3072
3584
4095
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted) (continued)
12-bit DAC, output specifications
PARAMETER
VO
TEST CONDITIONS
Output voltage
range
(see Note 1,
Figure 24)
CL(DAC12)
Max DAC12
load capacitance
IL(DAC12)
Max DAC12
load current
RO/P(DAC12)
Output
Resistance
(see Figure 24)
VCC
MIN
TYP
MAX
No Load, VeREF+ = AVCC,
DAC12_xDAT = 0h, DAC12IR = 1,
DAC12AMPx = 7
2.2V/3V
0
0.005
No Load, VeREF+ = AVCC,
DAC12_xDAT = 0FFFh, DAC12IR = 1,
DAC12AMPx = 7
2.2V/3V
AVCC−0.05
AVCC
UNIT
V
RLoad= 3 kΩ, VeREF+ = AVCC,
DAC12_xDAT = 0h, DAC12IR = 1,
DAC12AMPx = 7
2.2V/3V
0
0.1
RLoad= 3 kΩ, VeREF+ = AVCC,
DAC12_xDAT = 0FFFh, DAC12IR = 1,
DAC12AMPx = 7
2.2V/3V
AVCC−0.13
AVCC
2.2V/3V
100
2.2V
−0.5
+0.5
3V
−1.0
+1.0
RLoad= 3 kΩ, VO/P(DAC12) < 0.3 V,
DAC12AMPx = 7,
DAC12_xDAT = 0h
2.2V/3V
150
250
RLoad= 3 kΩ,
VO/P(DAC12) > AVCC−0.3 V
DAC12AMPx = 7,
DAC12_xDAT = 0FFFh
2.2V/3V
150
250
RLoad= 3 kΩ,
0.3V ≤ VO/P(DAC12) ≤ AVCC − 0.3V
DAC12AMPx = 7
2.2V/3V
1
4
pF
mA
Ω
NOTES: 1. Data is valid after the offset calibration of the output amplifier.
ILoad
RO/P(DAC12_x)
Max
RLoad
AV CC
DAC12
2
O/P(DAC12_x)
CLoad= 100pF
Min
0.3
AV CC−0.3V
VOUT
AV CC
Figure 24. DAC12_x Output Resistance Tests
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
41
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
12-bit DAC, reference input specifications
PARAMETER
TEST CONDITIONS
Reference input
voltage range
VeREF+
Ri(VREF+),
Ri(VeREF+)
NOTES: 1.
2.
3.
4.
5.
Reference input
resistance
DAC12IR=0, (see Notes 1 and 2)
VCC
2.2V/3V
DAC12IR=1, (see Notes 3 and 4)
2.2V/3V
DAC12_0 IR=DAC12_1 IR =0
2.2V/3V
DAC12_0 IR=1, DAC12_1 IR = 0
2.2V/3V
DAC12_0 IR=0, DAC12_1 IR = 1
2.2V/3V
DAC12_0 IR=DAC12_1 IR =1
DAC12_0 SREFx = DAC12_1 SREFx
(see Note 5)
2.2V/3V
MIN
TYP
MAX
AVCC/3
AVcc
AVCC+0.2
AVcc+0.2
20
UNIT
V
MΩ
40
48
56
kΩ
20
24
28
kΩ
For a full-scale output, the reference input voltage can be as high as 1/3 of the maximum output voltage swing (AVCC).
The maximum voltage applied at reference input voltage terminal VeREF+ = [AVCC − VE(O)] / [3*(1 + EG)].
For a full-scale output, the reference input voltage can be as high as the maximum output voltage swing (AVCC).
The maximum voltage applied at reference input voltage terminal VeREF+ = [AVCC − VE(O)] / (1 + EG).
When DAC12IR = 1 and DAC12SREFx = 0 or 1 for both channels, the reference input resistive dividers for each DAC are in parallel
reducing the reference input resistance.
12-bit DAC, dynamic specifications; Vref = VCC, DAC12IR = 1 (see Figure 25 and Figure 26)
PARAMETER
tON
tS(FS)
tS(C-C)
SR
DAC12 ontime
TEST CONDITIONS
DAC12_xDAT = 800h,
ErrorV(O) < ±0.5 LSB
(see Note 1,Figure 25)
Settling
time,full-scale
DAC12_xDAT =
80h→ F7Fh→ 80h
Settling time,
code to code
DAC12_xDAT =
3F8h→ 408h→ 3F8h
BF8h→ C08h→ BF8h
Slew Rate
DAC12_xDAT =
80h→ F7Fh→ 80h
Glitch energy: full-scale
DAC12_xDAT =
80h→ F7Fh→ 80h
DAC12AMPx=0 → {2, 3, 4}
VCC
2.2V/3V
MIN
TYP
MAX
DAC12AMPx=0 → {5, 6}
2.2V/3V
60
120
15
30
DAC12AMPx=0 → 7
2.2V/3V
6
12
DAC12AMPx=2
2.2V/3V
100
200
DAC12AMPx=3,5
2.2V/3V
40
80
DAC12AMPx=4,6,7
2.2V/3V
15
30
DAC12AMPx=2
2.2V/3V
5
DAC12AMPx=3,5
2.2V/3V
2
DAC12AMPx=4,6,7
2.2V/3V
1
DAC12AMPx=2
2.2V/3V
0.05
0.12
DAC12AMPx=3,5
2.2V/3V
0.35
0.7
DAC12AMPx=4,6,7
2.2V/3V
1.5
2.7
DAC12AMPx=2
2.2V/3V
10
DAC12AMPx=3,5
2.2V/3V
10
DAC12AMPx=4,6,7
2.2V/3V
10
NOTES: 1. RLoad and CLoad connected to AVSS (not AVCC/2) in Figure 25.
2. Slew rate applies to output voltage steps >= 200mV.
Conversion 1
VOUT
DAC Output
ILoad
RLoad = 3 kΩ
Glitch
Energy
Conversion 2
Conversion 3
+/− 1/2 LSB
AV CC
2
RO/P(DAC12.x)
+/− 1/2 LSB
CLoad = 100pF
tsettleLH
Figure 25. Settling Time and Glitch Energy Testing
42
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
tsettleHL
UNIT
µs
µs
µs
V/µs
nV-s
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
Conversion 1
Conversion 2
Conversion 3
VOUT
90%
90%
10%
10%
tSRLH
tSRHL
Figure 26. Slew Rate Testing
12-bit DAC, dynamic specifications continued (TA = 25°C unless otherwise noted)
PARAMETER
BW−3dB
TEST CONDITIONS
3-dB bandwidth,
VDC=1.5V, VAC=0.1VPP
(see Figure 27)
Channel-to-channel crosstalk
(see Note 1 and Figure 28)
VCC
MIN
DAC12AMPx = {2, 3, 4}, DAC12SREFx = 2,
DAC12IR = 1, DAC12_xDAT = 800h
2.2V/3V
40
DAC12AMPx = {5, 6}, DAC12SREFx = 2,
DAC12IR = 1, DAC12_xDAT = 800h
2.2V/3V
180
DAC12AMPx = 7, DAC12SREFx = 2,
DAC12IR = 1, DAC12_xDAT = 800h
2.2V/3V
550
DAC12_0DAT = 800h, No Load,
DAC12_1DAT = 80h<−>F7Fh, RLoad = 3kΩ
fDAC12_1OUT = 10kHz @ 50/50 duty cycle
2.2V/3V
DAC12_0DAT = 80h<−>F7Fh, RLoad = 3kΩ,
DAC12_1DAT = 800h, No Load
fDAC12_0OUT = 10kHz @ 50/50 duty cycle
2.2V/3V
TYP
MAX
UNIT
kHz
−80
dB
−80
NOTES: 1. RLOAD = 3 kΩ, CLOAD = 100 pF
ILoad
Ve REF+
RLoad = 3 kΩ
AV CC
DAC12_x
2
DACx
AC
CLoad = 100pF
DC
Figure 27. Test Conditions for 3-dB Bandwidth Specification
ILoad
RLoad
AV CC
DAC12_0
DAC12_xDAT 080h
2
DAC0
7F7h
080h
7F7h
080h
V OUT
CLoad= 100pF
VREF+
ILoad
Ve
V DAC12_yOUT
RLoad
AV CC
DAC12_1
V DAC12_xOUT
2
DAC1
fToggle
CLoad= 100pF
Figure 28. Crosstalk Test Conditions
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
43
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
operational amplifier OA, supply specifications
PARAMETER
VCC
ICC
PSRR
TEST CONDITIONS
Supply voltage
Supply current
(see Note 1)
Power supply rejection ratio
VCC
—
MIN
TYP
MAX
2.2
UNIT
3.6
Fast Mode, RRIP OFF
2.2 V/3 V
180
290
Medium Mode, RRIP OFF
2.2 V/3 V
110
190
Slow Mode, RRIP OFF
2.2 V/3 V
50
80
Fast Mode, RRIP ON
2.2 V/3 V
300
490
Medium Mode, RRIP ON
2.2 V/3 V
190
350
Slow Mode, RRIP ON
2.2 V/3 V
90
190
Non-inverting
2.2 V/3 V
70
V
µA
A
dB
NOTES: 1. P6SEL.x = 1 for each corresponding pin when used in OA input or OA output mode.
operational amplifier OA, input/output specifications
PARAMETER
VI/P
Voltage supply, I/P
IIkg
Input leakage current, I/P
(see Notes 1 and 2)
TEST CONDITIONS
RRIP OFF
VCC
—
RRIP ON
—
TA = −40 to +55_C
TA = +55 to +85_C
—
−5
—
−20
Fast Mode
—
Medium Mode
Vn
Voltage noise density, I/P
—
50
—
65
2.2 V/3 V
RO/P
(OAx)
CMRR
Common-mode rejection ratio
NOTES: 1.
2.
3.
4.
44
Fast Mode, ISOURCE ≤ −500µA
2.2 V
Slow Mode,ISOURCE ≤ −150µA
3V
Fast Mode, ISOURCE ≤ +500µA
2.2 V
Slow Mode,ISOURCE ≤ +150µA
3V
±10
±1.5
mV/V
VCC−0.2
VCC−0.1
VCC
VCC
V
VSS
VSS
0.2
0.1
2.2 V/3 V
150
250
RLoad= 3 kΩ, CLoad = 50pF, RRIP ON,
VO/P(OAx) > AVCC − 0.2 V
2.2 V/3 V
150
250
RLoad= 3 kΩ, CLoad = 50pF, RRIP ON,
0.2 V ≤ VO/P(OAx) ≤ AVCC − 0.2 V
2.2 V/3 V
0.1
4
Non-inverting
2.2 V/3 V
70
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
mV
µV/°C
RLoad= 3 kΩ, CLoad = 50pF, RRIP ON,
VO/P(OAx) < 0.2 V
ESD damage can degrade input current leakage.
The input bias current is overridden by the input leakage current.
Characterized and calculated using the box method, not production tested.
Specification valid for voltage-follower OAx configuration.
V
nV/√Hz
±10
2.2 V/3 V
0.3V ≤ VIN ≤ VCC−0.3V
∆VCC≤ ± 10%, TA = 25°C
Output
Resistance
(see Figure 29 and Note 4)
nA
30
Offset voltage drift
with supply, I/P
V
50
—
2.2 V/3 V
Low-level output voltage, O/P
20
Fast Mode
see Note 3
VOL
nA
±5
80
Offset temperature drift, I/P
UNIT
±0.5
140
fV(I/P) = 10 kHz
MAX
VCC−1.2
VCC+0.1
5
−0.1
—
Offset voltage, I/P
High-level output voltage, O/P
−0.1
—
fV(I/P) = 1 kHz
Slow Mode
VOH
TYP
Slow Mode
Medium Mode
VIO
MIN
V
Ω
dB
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
RO/P(OAx)
Max
RLoad
ILoad
AV CC
OAx
2
CLoad
O/P(OAx)
Min
0.2V
AV CC −0.2VAV
V
CC OUT
Figure 29. OAx Output Resistance Tests
operational amplifier OA, dynamic specifications
PARAMETER
TEST CONDITIONS
VCC
—
Fast Mode
SR
Slew rate
GBW
TYP
MAX
UNIT
1.2
Medium Mode
—
0.8
Slow Mode
—
0.3
—
100
dB
Open-loop voltage gain
φm
MIN
V/µs
Phase margin
CL = 50 pF
—
60
deg
Gain margin
CL = 50 pF
—
20
dB
Gain-Bandwidth Product
(see Figure 30
and Figure 31)
Non−inverting, Fast Mode, RL = 47kΩ, CL = 50pF
2.2 V/3 V
2.2
Non−inverting, Medium Mode, RL =300kΩ, CL = 50pF
2.2 V/3 V
1.4
Non−inverting, Slow Mode, RL =300kΩ, CL = 50pF
2.2 V/3 V
0.5
ton, non-inverting, Gain = 1
2.2 V/3 V
10
ten(on) Enable time on
ten(off) Enable time off
MHz
2.2 V/3 V
20
µs
1
µs
TYPICAL PHASE vs FREQUENCY
TYPICAL OPEN-LOOP GAIN vs FREQUENCY
0
140
120
Fast Mode
100
−50
Medium Mode
60
40
20
Slow Mode
0
Phase − degrees
Gain − dB
80
Fast Mode
−100
Medium Mode
−150
−20
Slow Mode
−40
−200
−60
−80
0.001
0.01
0.1
1
10
100
Input Frequency − kHz
1000 10000
−250
1
10
100
1000
10000
Input Frequency − kHz
Figure 31
Figure 30
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
45
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
electrical characteristics over recommended operating free-air temperature (unless otherwise
noted)
Flash Memory
TEST
CONDITIONS
PARAMETER
VCC(PGM/
ERASE)
VCC
Program and Erase supply voltage
MIN
NOM
2.7
fFTG
IPGM
Flash Timing Generator frequency
257
IERASE
tCPT
Supply current from DVCC during erase
Cumulative program time
see Note 1
2.7 V/ 3.6 V
tCMErase
Cumulative mass erase time
see Note 2
2.7 V/ 3.6 V
Supply current from DVCC during program
UNIT
3.6
V
476
kHz
2.7 V/ 3.6 V
3
5
mA
2.7 V/ 3.6 V
3
7
mA
4
ms
Program/Erase endurance
TJ = 25°C
200
104
ms
105
tRetention
Data retention duration
tWord
tBlock, 0
Word or byte program time
Block program time for 1st byte or word
tBlock, 1-63
tBlock, End
Block program time for each additional byte or word
tMass Erase
tSeg Erase
Mass erase time
5297
Segment erase time
4819
Block program end-sequence wait time
MAX
cycles
100
years
35
30
21
see Note 3
tFTG
6
NOTES: 1. The cumulative program time must not be exceeded when writing to a 64-byte flash block. This parameter applies to all programming
methods: individual word/byte write and block write modes.
2. The mass erase duration generated by the flash timing generator is at least 11.1ms ( = 5297x1/fFTG,max = 5297x1/476kHz). To
achieve the required cumulative mass erase time the Flash Controller’s mass erase operation can be repeated until this time is met.
(A worst case minimum of 19 cycles are required).
3. These values are hardwired into the Flash Controller’s state machine (tFTG = 1/fFTG).
JTAG Interface
TEST
CONDITIONS
PARAMETER
fTCK
TCK input frequency
see Note 1
RInternal
Internal pull-up resistance on TMS, TCK, TDI/TCLK
see Note 2
VCC
MIN
2.2 V
3V
2.2 V/ 3 V
25
MIN
NOM
MAX
UNIT
0
5
MHz
0
10
MHz
60
90
kΩ
NOM
MAX
NOTES: 1. fTCK may be restricted to meet the timing requirements of the module selected.
2. TMS, TDI/TCLK, and TCK pull-up resistors are implemented in all versions.
JTAG Fuse (see Note 1)
TEST
CONDITIONS
PARAMETER
VCC(FB)
VFB
Supply voltage during fuse-blow condition
IFB
tFB
Supply current into TDI/TCLK during fuse blow
TA = 25°C
Voltage level on TDI/TCLK for fuse-blow: F versions
VCC
2.5
6
Time to blow fuse
UNIT
V
7
V
100
mA
1
ms
NOTES: 1. Once the fuse is blown, no further access to the MSP430 JTAG/Test and emulation features is possible. The JTAG block is switched
to bypass mode.
46
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
APPLICATION INFORMATION
input/output schematic
Port P1, P1.0 to P1.5, input/output with Schmitt-trigger
Pad Logic
DVSS
DVSS
CAPD.x
P1SEL.x
0: Input
1: Output
0
P1DIR.x
Direction Control
From Module
1
0
1
P1OUT.x
Module X OUT
Bus
Keeper
P1.0/TA0
P1.1/TA0/MCLK
P1.2/TA1
P1.3/TBOUTH/SVSOUT
P1.4/TBCLK/SMCLK
P1.5/TACLK/ACLK
P1IN.x
EN
Module X IN
D
P1IE.x
P1IRQ.x
P1IFG.x
EN
Interrupt
Edge
Select
Q
Set
P1IES.x
P1SEL.x
Note: 0 ≤ x ≤ 5
Note: Port function is active if CAPD.x = 0
PnSEL.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
Module X IN
PnIE.x
PnIFG.x
P1SEL.0
P1DIR.0
P1DIR.0
P1OUT0
†
Out0 sig.
P1IN.0
CCI0A†
P1IE.0
P1IFG.0
P1IES.0
P1IN.1
†
CCI0B
P1IE.1
P1IFG.1
P1IES.1
P1IN.2
†
CCI1A
P1IE.2
P1IFG.2
P1IES.2
P1IE.3
P1IFG.3
P1IES.3
P1IE.4
P1IFG.4
P1IES.4
P1IE.5
P1IFG.5
P1IES.5
P1SEL.1
P1DIR.1
P1SEL.2
P1DIR.2
P1DIR.1
P1DIR.2
P1OUT.1
MCLK
P1OUT.2
†
Out1 sig.
P1SEL.3
P1DIR.3
P1DIR.3
P1OUT.3
SVSOUT
P1IN.3
‡
TBOUTH
P1SEL.4
P1DIR.4
P1DIR.4
P1OUT.4
SMCLK
P1IN.4
TBCLK
P1SEL.5
P1DIR.5
P1DIR5
P1OUT.5
ACLK
P1IN.5
TACLK
‡
†
PnIES.x
† Timer_A
‡ Timer_B
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
47
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
Port P1, P1.6, P1.7, input/output with Schmitt-trigger
Pad Logic
Note: Port function is active if CAPD.6 = 0
CAPD.6
P1SEL.6
0: Input
1: Output
0
P1DIR.6
P1.6/
CA0
1
P1DIR.6
0
P1OUT.6
1
DVSS
Bus
Keeper
P1IN.6
EN
unused
D
P1IE.7
P1IRQ.07
EN
Interrupt
Edge
Select
Q
P1IFG.7
Set
P1IES.x
P1SEL.x
Comparator_A
P2CA
AVcc
CAREF
CAEX
CA0
CAF
CCI1B
+
to Timer_Ax
−
CA1
2
CAREF
Reference Block
Pad Logic
CAPD.7
Note: Port function is active if CAPD.7 = 0
P1SEL.7
0: input
1: output
0
P1DIR.7
P1.7/
CA1
1
P1DIR.7
0
P1OUT.7
1
DVSS
Bus
keeper
P1IN.7
EN
unused
D
P1IE.7
P1IRQ.07
EN
Q
P1IFG.7
Set
Interrupt
Edge
Select
P1IES.7
48
P1SEL.7
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P2, P2.0, P2.4 to P2.5, input/output with Schmitt-trigger
Pad Logic
DVSS
DVSS
P2SEL.x
0: Input
1: Output
0
P2DIR.x
Direction Control
From Module
1
0
1
P2OUT.x
Module X OUT
Bus
Keeper
P2.0/TA2
P2.4/UTXD0
P2IN.x
P2.5/URXD0
EN
Module X IN
D
P2IE.x
P2IRQ.x
P2IFG.x
EN
Interrupt
Edge
Select
Q
Set
P2IES.x
Note:
P2SEL.x
x {0,4,5}
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
P2Sel.0
P2DIR.0
P2DIR.0
P2OUT.0
P2Sel.4
P2DIR.4
DVCC
P2Sel.5
P2DIR.5
DVSS
Module X
OUT
PnIN.x
Module X IN
PnIE.x
PnIFG.x
Out2 sig. †
P2IN.0
CCI2A †
P2IE.0
P2IFG.0
P2IES.0
P2OUT.4
‡
UTXD0
P2IN.4
unused
P2IE.4
P2IFG.4
P2IES.4
P2OUT.5
DVSS
P2IN.5
URXD0
P2IE.5
P2IFG.5
P2IES.5
‡
PnIES.x
†Timer_A
‡USART0
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
49
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P2, P2.1 to P2.3, input/output with Schmitt-trigger
Pad Logic
DVSS
DVSS
Module IN of pin
P1.3/TBOUTH/SVSOUT
P1DIR.3
P1SEL.3
P2SEL.x
0: Input
1: Output
0
P2DIR.x
Direction Control
From Module
P2OUT.x
1
0
1
Module X OUT
Bus
Keeper
P2.1/TB0
P2.2/TB1
P2IN.x
P2.3/TB2
EN
D
Module X IN
P2IE.x
P2IRQ.x
Q
P2IFG.x
EN
Interrupt
Edge
Select
Set
P2IES.x
Note:
P2SEL.x
1<x <3
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
P2Sel.1
P2DIR.1
P2DIR.1
P2OUT.1
Out0 sig. †
P2IN.1
Module X IN
PnIE.x
PnIFG.x
CCI0A †
CCI0B
P2IE.1
P2IFG.1
P2IES.1
P2IE.2
P2IFG.2
P2IES.2
P2IE.3
P2IFG.3
P2IES.3
P2Sel.2
P2DIR.2
P2DIR.2
P2OUT.2
Out1 sig. †
P2IN.2
CCI1A †
CCI1B
P2Sel.3
P2DIR.3
P2DIR.3
P2OUT.3
Out2 sig. †
P2IN.3
CCI2A †
CCI2B
†Timer_B
50
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
PnIES.x
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P2, P2.6 to P2.7, input/output with Schmitt-trigger
0: Port active
1: Segment xx function active
Pad Logic
Port/LCD‡
Segment xx‡
P2SEL.x
0: Input
1: Output
0
P2DIR.x
Direction Control
From Module
1
0
P2OUT.x
1
Module X OUT
Bus
Keeper
P2.6/CAOUT/S19
P2.7/ADC12CLK/S18
P2IN.x
EN
D
Module X IN
P2IE.x
P2IRQ.x
P2IFG.x
EN
Q
Set
Interrupt
Edge
Select
P2IES.x
Note:
P2SEL.x
6<x <7
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
Module X IN
PnIE.x
PnIFG.x
PnIES.x
Port/LCD
P2Sel.6
P2DIR.6
P2DIR.6
P2OUT.6
CAOUT †
P2IN.6
unused
P2IE.6
P2IFG.6
P2IES.6
0: LCDM<40h
P2Sel.7
P2DIR.7
P2DIR.7
P2OUT.7
ADC12CLK§
P2IN.7
unused
P2IE.7
P2IFG.7
P2IES.7
0: LCDM<40h
† Comparator_A
§ ADC12
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
51
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P3, P3.0 to P3.3, input/output with Schmitt-trigger
MSP430x43xIPN (80-Pin) Only
0: Port active
1: Segment xx function active
LCDM.5
LCDM.6
LCDM.7
Pad Logic
Segment xx
x43xIPZ and x44xIPZ have not segment
Function on Port P3: Both lines are low.
P3SEL.x
0: Input
1: Output
0
P3DIR.x
Direction Control
From Module
1
0
1
P3OUT.x
Module X OUT
Bus
Keeper
P3.0/STE0/S31
P3.1/SIMO0/S30
P3.2/SOMI0/S29
P3.3/UCLK0/S28
P3IN.x
EN
Module X IN
Note:
D
0<x<3
Direction
PnOUT.x
Control
From Module
Module X
OUT
PnIN.x
Module X IN
DVSS
P3IN.0
STE0(in)
DCM_SIMO0 P3OUT.1
SIMO0(out)
P3IN.1
SIMO0(in)
P3DIR.2
DCM_SOMI0 P3OUT.2
SOMIO(out)
P3IN.2
SOMI0(in)
P3DIR.3
DCM_UCLK0 P3OUT.3
UCLK0(out)
P3IN.3
UCLK0(in)
PnSel.x
PnDIR.x
P3Sel.0
P3DIR.0
P3Sel.1
P3DIR.1
P3Sel.2
P3Sel.3
DVSS
P3OUT.0
Direction Control for SIMO0 and UCLK0
SYNC
MM
52
DCM_SIMO0
DCM_UCLK0
Direction Control for SOMI0
SYNC
MM
STC
STC
STE
STE
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
DCM_SOMI0
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P3, P3.4 to P3.7, input/output with Schmitt-trigger
0: Port active
1: Segment xx function active
Pad Logic
LCDM.7
Segment xx
P3SEL.x
0: Input
1: Output
0
P3DIR.x
Direction Control
From Module
1
0
P3OUT.x
1
Module X OUT
Bus
Keeper
P3.4/S27
P3.5/S26
P3.6/S25/DMAE0
P3.7/S24
P3IN.x
EN
D
Module X IN
Note:
4<x <7
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
Module X IN
P3SEL.4
P3DIR.4
P3DIR.4
P3OUT.4
DVSS
P3IN.4
unused
P3SEL.5
P3DIR.5
P3DIR.5
P3OUT.5
DVSS
P3IN.5
unused
P3SEL.6
P3DIR.6
P3DIR.6
P3OUT.6
DVSS
P3IN.6
DMAE0
P3SEL.7
P3DIR.7
P3DIR.7
P3OUT.7
DVSS
P3IN.7
unused
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
53
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P4, P4.0 to P4.5, input/output with Schmitt-trigger
0: Port active
1: Segment xx function active
Pad Logic
Port/LCD
Segment xx
P4SEL.x
0: Input
1: Output
0
P4DIR.x
Direction Control
From Module
1
0
1
P4OUT.x
Module X OUT
Bus
Keeper
P4.0/S9
P4.1/S8
P4.2/S7
P4.3/S6
P4.4/S5
P4.5/S4
P4IN.x
EN
Module X IN
Note:
D
0<x<5
PnSEL.x
PnDIR.x
Direction
Control
From Module
P4SEL.0
P4DIR.0
P4DIR.0
P4OUT.0
P4SEL.1
P4DIR.1
P4DIR.1
P4SEL.2
P4DIR.2
P4SEL.3
Module X IN
DVSS
P4IN.0
unused
P4OUT.1
DVSS
P4IN.1
unused
P4DIR.2
P4OUT.2
DVSS
P4IN.2
unused
P4DIR.3
P4DIR.3
P4OUT.3
DVSS
P4IN.3
unused
P4SEL.4
P4DIR.4
P4DIR.4
P4OUT.4
DVSS
P4IN.4
unused
P4SEL.5
P4DIR.5
P4DIR.5
P4OUT.5
DVSS
P4IN.5
unused
DEVICE
54
Module X
PnIN.x
xG43xIPN 80-pin QFP
PnOUT.x
OUT
PORT BITS
PORT FUNCTION
LCD SEG. FUNCTION
P4.0 to P4.5
LCDM < 020h
LVDM ≥ 020h
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P4, P4.6, input/output with Schmitt-trigger
INCH=15#
a15 #
0: Segment S3 disabled
1: Segment S3 enabled
Pad Logic
1, if LCDM > 020h
Segment S3
P4SEL.6
0: input
1: output
0
P4DIR.6
Direction Control
From Module
1
0
P4OUT.6
1
Module XOUT
Bus
keeper
P4.6/S3/A15
P4IN.6
EN
D
Module X IN
#
Signal from or to ADC12
PnSEL.x
P4SEL.6
DEVICE
xG43xIPN 80-pin QFP
PnDIR.x
P4DIR.6
Direction
PnOUT.x
Control
From Module
P4DIR.6
P4OUT.6
Module X
OUT
DVSS
PnIN.x
Module X IN
P4IN.6
unused
PORT BITS
PORT FUNCTION
LCD SEG. FUNCTION
P4.6
LCDM < 020h
LVDM ≥ 020h
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
55
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P4, P4.7, input/output with Schmitt-trigger
INCH=14#
a14 #
0: Segment S2 disabled
1: Segment S2 enabled
Pad Logic
1, if LCDM > 020h
Segment S2
P4SEL.7
0: input
1: output
0
P4DIR.7
Direction Control
From Module
1
0
P4OUT.7
1
Module XOUT
Bus
keeper
P4.7/S2/A14
P4IN.7
EN
D
Module X IN
#
Signal from or to ADC12
PnSel.x
PnDIR.x
P4Sel.7
P4DIR.7
DEVICE
xG43xIPN 80-pin QFP
56
Direction
PnOUT.x
Control
From Module
P4DIR.7
P4OUT.7
Module X
OUT
DVSS
PnIN.x
Module X IN
P4IN.7
Unused
PORT BITS
PORT FUNCTION
LCD SEG. FUNCTION
P4.7
LCDM < 020h
LVDM ≥ 020h
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P5, P5.0, input/output with Schmitt-trigger
INCH=13#
a13 #
0: Segment S1 disabled
1: Segment S1 enabled
Pad Logic
1, if LCDM > 020h
Segment S1
P5SEL.0
0: input
1: output
0
P5DIR.0
Direction Control
From Module
1
0
P5OUT.0
1
Module XOUT
Bus
keeper
P5.0/S1/A13
P5IN.0
EN
D
Module X IN
#
Signal from or to ADC12
PnSEL.x
P5SEL.0
DEVICE
xG43xIPN 80-pin QFP
PnDIR.x
P5DIR.0
Direction
PnOUT.x
Control
From Module
P5DIR.0
P5OUT.0
Module X
OUT
DVSS
PnIN.x
Module X IN
P5IN.0
unused
PORT BITS
PORT FUNCTION
LCD SEG. FUNCTION
P5.0
LCDM < 020h
LVDM ≥ 020h
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
57
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P5, P5.1, input/output with Schmitt-trigger
OA0ADC0
INCH=12#
a12 #
0: Segment S0 disabled
1: Segment S0 enabled
1, if LCDM > 020h
Pad Logic
DAC12.1OPS
Segment S0
P5SEL.1
0: input
1: output
0
P5DIR.1
Direction Control
From Module
1
0
P5OUT.1
1
Module XOUT
Bus
keeper
P5.1/S0/
A12/DAC1
P5IN.1
EN
Module X IN
D
’0’, if DAC12.1CALON=0 AND
DAC12.1AMPx>1 AND DAC12.1OPS=1
+
1
0
−
’1’, if DAC12.1AMPx>1
’1’, if DAC12.1AMPx=1
DAC12.1OPS
DAC12.1OPS
1
P6.7/A7/
DAC1/SVSIN
DAC1_2_OA
#
0
Signal from or to ADC12
Function
Description
P5SEL.1
LCDM
DAC12.1OPS
DAC12.1AMPx
DAC12
3-State
X
X
1
=0
0V
X
X
1
=1
DAC1 output
X
X
1
>1
(the o/p voltage can be converted with ADC12, channel A12)
ADC12
Channel 12, A12
1
X
0
X
LCD
Segment S0, initial state
0
≥ 20h
0
X
Port
P5.1
0
< 20h
0
X
58
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P5, P5.1, input/output with Schmitt-trigger (continued)
PnSEL.x
PnDIR.x
Dir. Control
from Module
PnOUT.x
Module X
OUT
PnIN.x
Module X
IN
Segment
Port/LCD
P5SEL.1
P5DIR.1
P5DIR.1
P5OUT.1
DVSS
P5IN.1
Unused
S0
0: LCDM<20h
port P5, P5.2 to P5.4, input/output with Schmitt-trigger
0: Port active
1: LCD function active
Port/LCD
LCD signal
Pad Logic
P5SEL.x
0: Input
1: Output
0
P5DIR.x
Direction Control
From Module
1
0
1
P5OUT.x
Module X OUT
Bus
Keeper
P5.2/COM1
P5.3/COM2
P5.4/COM3
P5IN.x
EN
Module X IN
D
Note:
2<x <4
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
Module X IN
LCD signal
Port/LCD
P5Sel.2
P5DIR.2
P5DIR.2
P5OUT.2
DVSS
P5IN.2
Unused
COM1
P5SEL.2
P5Sel.3
P5DIR.3
P5DIR.3
P5OUT.3
DVSS
P5IN.3
Unused
COM2
P5SEL.3
P5Sel.4
P5DIR.4
P5DIR.4
P5OUT.4
DVSS
P5IN.4
Unused
COM3
P5SEL.4
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
59
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P5, P5.5 to P5.7, input/output with Schmitt-trigger
0: Port active
1: LCD function active
Port/LCD
LCD signal
Pad Logic
P5SEL.x
0: Input
1: Output
0
P5DIR.x
Direction Control
From Module
1
0
1
P5OUT.x
Module X OUT
Bus
Keeper
P5.5/R13
P5.6/R23
P5.7/R33
P5IN.x
EN
Module X IN
D
Note:
60
5<x <7
PnSel.x
PnDIR.x
Dir. Control
from module
PnOUT.x
Module X
OUT
PnIN.x
Module X IN
LCD signal
Port/LCD
P5Sel.5
P5DIR.5
P5DIR.5
P5OUT.5
DVSS
P5IN.5
Unused
R13
P5SEL.5
P5Sel.6
P5DIR.6
P5DIR.6
P5OUT.6
DVSS
P5IN.6
Unused
R23
P5SEL.6
P5Sel.7
P5DIR.7
P5DIR.7
P5OUT.7
DVSS
P5IN.7
Unused
R33
P5SEL.7
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.0, P6.2, and P6.4, input/output with Schmitt-trigger
INCH=x
ax
†, #
†, #
P6SEL.x
†
†
P6DIR.x
Direction Control
From Module
†
P6OUT.x
0
1
0
1
Module XOUT
P6IN.x
Pad Logic
0: input
1: output
Bus
keeper
P6.0/A0/OA0I0
P6.2/A2/OA0I1
P6.4/A4/OA1I0
†
EN
Module X IN
†
D
+
−
† x = {0, 2, 4}
#
OA0 / OA1
Signal from or to ADC12
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.0
P6DIR.0
P6DIR.0
P6OUT.0
DVSS
P6IN.0
unused
P6Sel.2
P6DIR.2
P6DIR.2
P6OUT.2
DVSS
P6IN.2
unused
P6Sel.4
P6DIR.4
P6DIR.4
P6OUT.4
DVSS
P6IN.4
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
61
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.1, input/output with Schmitt-trigger
INCH=1#
a1 #
P6SEL.1
0
P6DIR.1
Direction Control
From Module
P6OUT.1
Pad Logic
0: input
1: output
1
0
1
Module XOUT
Bus
keeper
P6.1/A1/OA0O
P6IN.1
EN
Module X IN
D
’1’, if OAADC1 = 1 OR OAFCx = 0
0
+
OA0
1
−
#
OA0
Signal from or to ADC12
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.1
P6DIR.1
P6DIR.1
P6OUT.1
DVSS
P6IN.1
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
62
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.3, input/output with Schmitt-trigger
INCH=3#
a3 #
P6SEL.3
0
P6DIR.3
Direction Control
From Module
P6OUT.3
Pad Logic
0: input
1: output
1
0
1
Module XOUT
Bus
keeper
P6.3/A3/OA1I1/OA1O
P6IN.3
EN
Module X IN
D
’1’, if OAADC1 = 1 OR OAFCx = 0
0
+
OA1
1
−
#
OA1
Signal from or to ADC12
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.3
P6DIR.3
P6DIR.3
P6OUT.3
DVSS
P6IN.3
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
63
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.5, input/output with Schmitt-trigger
INCH=5#
a5 #
P6SEL.5
0
P6DIR.5
Direction Control
From Module
P6OUT.5
Pad Logic
0: input
1: output
1
0
1
Module XOUT
Bus
keeper
P6.5/A5/OA2I1/OA2O
P6IN.5
EN
Module X IN
D
’1’, if OAADC1 = 1 OR OAFCx = 0
0
+
OA2
1
−
#
OA2
Signal from or to ADC12
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.5
P6DIR.5
P6DIR.5
P6OUT.5
DVSS
P6IN.5
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
64
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.6, input/output with Schmitt-trigger
0: Port active, T−Switch off
1: T−Switch is on, Port disabled
INCH=6#
a6 #
’1’, if DAC12.0AMP>0
DAC12.0OPS
P6SEL.6
P6DIR.6
0
P6DIR.6
1
0: input
1: output
Pad Logic
0
P6OUT.6
1
DVSS
Bus
keeper
P6.6/A6/DAC0/OA2I0
P6IN.6
EN
D
’0’, if DAC12CALON = 0 AND
DAC12AMPx>1 AND DAC12OPS = 0
+
1
0
−
’1’, if DAC12AMPx>1
#
Signal from or to ADC12
’1’, if DAC12AMPx=1
DAC12OPS
DAC12OPS
0
Ve REF+/DAC0
DAC0_2_OA
1
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.6
P6DIR.6
P6DIR.6
P6OUT.6
DVSS
P6IN.6
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
65
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
port P6, P6.7, input/output with Schmitt-trigger
To SVS Mux (15) $
0: Port active, T−Switch off
1: T−Switch is on, Port disabled
INCH=7#
a7 #
’1’, if DAC12.1AMP>0
DAC12.1OPS
’1’, if VLD=15 *
P6SEL.7
P6DIR.7
0: input
1: output
0
Pad Logic
1
P6DIR.7
0
P6OUT.7
1
DVSS
Bus
keeper
P6.7/A7/
DAC1/SVSIN
P6IN.7
EN
D
’0’, if DAC12CALON = 0 AND
DAC12AMPx>1 AND DAC12OPS = 0
+
1
0
−
’1’, if DAC12AMPx>1
’1’, if DAC12AMPx=1
DAC12OPS
DAC12OPS
0
P5.1/S0/
A12/DAC1
DAC1_2_OA
1
#
Signal from or to ADC12
$
Signal to SVS block, selected if VLD=15
*
VLD control bits are located in SVS
PnSel.x
PnDIR.x
Dir. Control
From Module
PnOUT.x
Module X OUT
PnIN.x
Module X IN
P6Sel.7
P6DIR.7
P6DIR.7
P6OUT.7
DVSS
P6IN.7
unused
NOTE: The signal at pins P6.x/Ax is used by the 12-bit ADC module.
The signal at pin P6.7/A7/SVSIN is also connected to the input multiplexer in the module brownout/supply voltage supervisor.
66
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
VeREF+/DAC0
DAC12.0OPS
0
DAC0_2_OA
P6.6/A6/DAC0/OA2I0
1
Reference Voltage to DAC1
Reference Voltage to ADC12
Reference Voltage to DAC0
#
Ve REF+ /DAC0
’0’, if DAC12CALON = 0
DAC12AMPx>1 AND DAC12OPS=1
+
−
1
0
’1’, if DAC12AMPx>1
’1’, if DAC12AMPx=1
DAC12OPS
#
If the reference of DAC0 is taken from pin VeREF+ /DAC0, unpredictable voltage levels will be on pin.
In this situation, the DAC0 output is fed back to its own reference input.
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
67
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
input/output schematic (continued)
JTAG pins TMS, TCK, TDI/TCLK, TDO/TDI, input/output with Schmitt-trigger or output
TDO
Controlled by JTAG
Controlled by JTAG
TDO/TDI
JTAG
Controlled
by JTAG
DVCC
TDI
Burn and Test
Fuse
TDI/TCLK
Test
and
Emulation
DVCC
TMS
Module
TMS
DVCC
TCK
TCK
RST/NMI
Tau ~ 50 ns
Brownout
TCK
68
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
G
D
U
S
G
D
U
S
SLAS380A − APRIL 2004 − REVISED SEPTEMBER 2004
JTAG fuse check mode
MSP430 devices that have the fuse on the TDI/TCLK 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 (I(TF) ) of 1 mA at 3 V can flow from the TDI/TCLK 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 after power up or if the
TMS is being held low during power up. 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.
The fuse check current only flows when the fuse check mode is active and the TMS pin is in a low state (see
Figure 32). Therefore, the additional current flow can be prevented by holding the TMS pin high (default
condition). The JTAG pins are terminated internally and therefore do not require external termination.
Time TMS Goes Low After POR
TMS
I(TF)
ITDI/TCLK
Figure 32. Fuse Check Mode Current
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
69
MECHANICAL DATA
MTQF010A – JANUARY 1995 – REVISED DECEMBER 1996
PN (S-PQFP-G80)
PLASTIC QUAD FLATPACK
0,27
0,17
0,50
0,08 M
41
60
61
40
80
21
0,13 NOM
1
20
Gage Plane
9,50 TYP
12,20
SQ
11,80
14,20
SQ
13,80
0,25
0,05 MIN
0°– 7°
0,75
0,45
1,45
1,35
Seating Plane
0,08
1,60 MAX
4040135 / B 11/96
NOTES: A. All linear dimensions are in millimeters.
B. This drawing is subject to change without notice.
C. Falls within JEDEC MS-026
POST OFFICE BOX 655303
• DALLAS, TEXAS 75265
1
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