Datasheet Texas Instruments MSP430F2617 — 数据表
制造商 | Texas Instruments |
系列 | MSP430F2617 |
16位超低功耗MCU,92KB闪存,8KB RAM,12位ADC,双DAC,2个USCI,HW Mult,DMA
数据表
MSP430F241x, MSP430F261x Mixed Signal Microcontroller datasheet
PDF, 1.9 Mb, 修订版: K, 档案已发布: Nov 8, 2012
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价格
状态
MSP430F2617TPM | MSP430F2617TPMR | MSP430F2617TPN | MSP430F2617TPNR | MSP430F2617TZQW | MSP430F2617TZQWR | |
---|---|---|---|---|---|---|
Lifecycle Status | Active (Recommended for new designs) | Active (Recommended for new designs) | Active (Recommended for new designs) | Active (Recommended for new designs) | Active (Recommended for new designs) | Active (Recommended for new designs) |
Manufacture's Sample Availability | No | No | No | Yes | Yes | Yes |
打包
MSP430F2617TPM | MSP430F2617TPMR | MSP430F2617TPN | MSP430F2617TPNR | MSP430F2617TZQW | MSP430F2617TZQWR | |
---|---|---|---|---|---|---|
N | 1 | 2 | 3 | 4 | 5 | 6 |
Pin | 64 | 64 | 80 | 80 | 113 | 113 |
Package Type | PM | PM | PN | PN | ZQW | ZQW |
Industry STD Term | LQFP | LQFP | LQFP | LQFP | BGA MICROSTAR JUNIOR | BGA MICROSTAR JUNIOR |
JEDEC Code | S-PQFP-G | S-PQFP-G | S-PQFP-G | S-PQFP-G | S-PBGA-N | S-PBGA-N |
Package QTY | 160 | 1000 | 119 | 1000 | 250 | 2500 |
Carrier | JEDEC TRAY (10+1) | LARGE T&R | JEDEC TRAY (10+1) | LARGE T&R | JEDEC TRAY (10+1) | LARGE T&R |
Device Marking | M430F2617T | M430F2617T | M430F2617T | M430F2617T | M430F2617T | M430F2617T |
Width (mm) | 10 | 10 | 12 | 12 | 7 | 7 |
Length (mm) | 10 | 10 | 12 | 12 | 7 | 7 |
Thickness (mm) | 1.4 | 1.4 | 1.4 | 1.4 | .74 | .74 |
Pitch (mm) | .5 | .5 | .5 | .5 | .5 | .5 |
Max Height (mm) | 1.6 | 1.6 | 1.6 | 1.6 | 1 | 1 |
Mechanical Data | 下载 | 下载 | 下载 | 下载 | 下载 | 下载 |
参数化
Parameters / Models | MSP430F2617TPM | MSP430F2617TPMR | MSP430F2617TPN | MSP430F2617TPNR | MSP430F2617TZQW | MSP430F2617TZQWR |
---|---|---|---|---|---|---|
ADC | ADC12 - 8ch | ADC12 - 8ch | ADC12 - 8ch | ADC12 - 8ch | ADC12 - 8ch | ADC12 - 8ch |
AES | N/A | N/A | N/A | N/A | N/A | N/A |
Active Power, uA/MHz | 365 | 365 | 365 | 365 | 365 | 365 |
Additional Features | Watchdog,Temp Sensor,Brown Out Reset | Watchdog,Temp Sensor,Brown Out Reset | Watchdog,Temp Sensor,Brown Out Reset | Watchdog,Temp Sensor,Brown Out Reset | Watchdog,Temp Sensor,Brown Out Reset | Watchdog,Temp Sensor,Brown Out Reset |
BSL | UART | UART | UART | UART | UART | UART |
CPU | MSP430 | MSP430 | MSP430 | MSP430 | MSP430 | MSP430 |
Comparators | Yes | Yes | Yes | Yes | Yes | Yes |
DMA | 3 | 3 | 3 | 3 | 3 | 3 |
Frequency, MHz | 16 | 16 | 16 | 16 | 16 | 16 |
GPIO Pins | 48 | 48 | 48 | 48 | 48 | 48 |
I2C | 2 | 2 | 2 | 2 | 2 | 2 |
Max VCC | 3.6 | 3.6 | 3.6 | 3.6 | 3.6 | 3.6 |
Min VCC | 1.8 | 1.8 | 1.8 | 1.8 | 1.8 | 1.8 |
Multiplier | 16x16 | 16x16 | 16x16 | 16x16 | 16x16 | 16x16 |
Non-volatile Memory, KB | 92 | 92 | 92 | 92 | 92 | 92 |
Operating Temperature Range, C | -40 to 105 | -40 to 105 | -40 to 105 | -40 to 105 | -40 to 105 | -40 to 105 |
Package Group | LQFP | LQFP | LQFP | LQFP | BGA MICROSTAR JUNIOR | BGA MICROSTAR JUNIOR |
Package Size: mm2:W x L, PKG | 64LQFP: 144 mm2: 12 x 12(LQFP) | 64LQFP: 144 mm2: 12 x 12(LQFP) | 64LQFP: 144 mm2: 12 x 12(LQFP) | 64LQFP: 144 mm2: 12 x 12(LQFP) | 113BGA MICROSTAR JUNIOR: 49 mm2: 7 x 7(BGA MICROSTAR JUNIOR) | 113BGA MICROSTAR JUNIOR: 49 mm2: 7 x 7(BGA MICROSTAR JUNIOR) |
RAM, KB | 8 | 8 | 8 | 8 | 8 | 8 |
Rating | Catalog | Catalog | Catalog | Catalog | Catalog | Catalog |
SPI | 2 | 2 | 2 | 2 | 2 | 2 |
Special I/O | N/A | N/A | N/A | N/A | N/A | N/A |
Standby Power, LPM3-uA | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 | 0.5 |
Timers - 16-bit | 2 | 2 | 2 | 2 | 2 | 2 |
UART | 2 | 2 | 2 | 2 | 2 | 2 |
Wakeup Time, us | 1 | 1 | 1 | 1 | 1 | 1 |
生态计划
MSP430F2617TPM | MSP430F2617TPMR | MSP430F2617TPN | MSP430F2617TPNR | MSP430F2617TZQW | MSP430F2617TZQWR | |
---|---|---|---|---|---|---|
RoHS | Compliant | Compliant | Compliant | Compliant | Compliant | Compliant |
应用须知
- Using the USCI I2C SlavePDF, 233 Kb, 档案已发布: Dec 21, 2007
This document is an overview of the use of the I2C slave function set for MSP430 devices with the USCI module. The functions provided in the package can be used for MSP430 slave devices performing I2C communication and can handle both transmit and receive requests from I2C masters.Note: The USCI I2C slave package includes a demonstration application that can be used on any MSP430 2xx device wi - Migrating From MSP430F16x to MSP430F261x (Rev. A)PDF, 120 Kb, 修订版: A, 档案已发布: Nov 12, 2008
The purpose of this application report is to facilitate the migration of MSP430F167/F168/F169/F1610/F1611/F1612-based designs to the MSP430F261x device family. In the course of this application report, the main differences between the two device families are highlighted, and migration solutions covering both software and hardware aspects are provided. - Extended Memory Access Using IAR v3.42A and CCE v2PDF, 205 Kb, 档案已发布: Nov 7, 2007
This application report describes how to access the extended memory in devices with memory greater than 64 KB using the large code/small data model supported by the IAR C/C++ compiler v3.42A and Code Composer Essentials (CCE) v2. The purpose of this application report is to provide an understanding of the extended features of the MSP430X CPU, customizing the linker command file to fit the target s - Migrating from the MSP430F2xx Family to the MSP430FR57xx Family (Rev. A)PDF, 154 Kb, 修订版: A, 档案已发布: Feb 16, 2012
This application report enables easy migration from MSP430F2xx Flash-based MCUs to the MSP430FR57xx family FRAM-based MCU. It covers programming, system, and peripheral considerations when migrating firmware. The purpose is to highlight differences between the two families. For more information on the usage of the MSP430FR57xx features, see the MSP430FR57xx Family User's Guide (Migrating from the USCI Module to the eUSCI Module (Rev. A)PDF, 41 Kb, 修订版: A, 档案已发布: Sep 13, 2012
The purpose of this application report is to enable easy migration for designs based on the USCI_A and USCI_B modules to the eUSCI_A and the eUSCI_B modules. The document highlights the new features in the eUSCI module and the main differences between the USCI and the eUSCI modules.Migrating From MSP430 F2xx and G2xx Families to MSP430 FR4xx and FR2xx Family (Rev. E)PDF, 237 Kb, 修订版: E, 档案已发布: May 4, 2018
This application report helps to ease the migration from MSP430F2xx flash-based MCUs to the MSP430FR4xx and MSP430FR2xx family of FRAM-based MCUs. It discusses programming system hardware core architecture and peripheral considerations. The intent is to highlight key differences between the two families. For more information on the use of the MSP430FR4xx and MSP430FR2xx devices see the MSP430Migrating from the MSP430F2xx,G2xx Family to the MSP430FR58xx/FR59xx/68xx/69xx (Rev. E)PDF, 179 Kb, 修订版: E, 档案已发布: Nov 3, 2016
This application report enables easy migration from MSP430F2xx flash-based MCUs to the MSP430FR58xx/FR59xx/68xx/69xx family of FRAM-based MCUs. For the migration guide to MSP430FR57xx, see Migrating From the MSP430F2xx Family to the MSP430FR57xx Family. It covers programming, system, and peripheral considerations when migrating firmware. The intent is to highlight key differences between the two fHDQ Protocol Implementation with MSP430PDF, 124 Kb, 档案已发布: Feb 19, 2004MSP430 Isolated FET InterfacePDF, 1.2 Mb, 档案已发布: Oct 10, 2003
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While spread-spectrum clocking has long since been used in processor and memory clock trees, there are many other clocked systems, such as power supplies or switch-mode amplifiers, that continue to use a single-frequency clock. This can, in turn, generate significant EMI and can make meeting governmental regulations for EMI challenging. These regulations typically set a limit on peak energy withinCurrent Transformer Phase Shift Compensation and CalibrationPDF, 63 Kb, 档案已发布: Jan 30, 2001
This application report demonstrates a digital technique to compensate and calibrate the phase shift of a current (or voltage) transformer used in electric power of energy measurement. Traditional analog compensation is replaced by a digital finite impulse response (FIR) filter. A technique emulating a non-unity power factor (non-UPF) load makes the calibration fully automatic. The calibration timGeneration and Recognition of DTMF Signals With the Microcontroller MSP430PDF, 233 Kb, 档案已发布: Oct 1, 1997
The first part of the Application Report describes the generation of DTMF signals using the Microcontroller MSP430. Following an explanation of the most important specifications which are involved, the theoretical and mathematical processes will be discussed with which sinusoidal waveforms can be derived from square-wave signals, by making use of appropriate analog filters. Tested examples of softEconomic Voltage Measurement With the MSP430 FamilyPDF, 91 Kb, 档案已发布: Oct 12, 1999
This application report describes voltage and current measurement methods using the MSP430 universal timer/port module. The report explains the two measurement methods (charge and discharge) and shows how to measure voltage and current. The equations for the calculations are also given. Further sections show additional applications such as the measurement of two voltage inputs, bridge arrangemSimple 1.5 V Boost Converter for MSP430PDF, 49 Kb, 档案已发布: Oct 18, 2000
A simple, efficient, low-cost, boost converter to take 1.5 V from a single type-AA alkaline battery to the operating voltage required by the MSP430 family of ultralow-power microcontrollers is described. Expected battery life is up to 1000 hours.Choosing an Ultra Low-Power MCUPDF, 306 Kb, 档案已发布: Jun 30, 2004
This application report describes how to compare ultralow-power MCUs. It discusses the key differences between popular low-power MCUs and how to interpret features and specifications and apply them to application requirements.MSP430 LFXT1 Oscillator AccuracyPDF, 184 Kb, 档案已发布: Nov 15, 2004
This report details the factors that influence achievable accuracy of the low frequency oscillator, specifically for real-time clock (RTC) applications. The intent of this application report is to provide an understanding of MSP430-specific factors influencing real-world achievable RTC accuracy using the LFXT1 oscillator with a standard 32.768 kHz watch crystal and present measurement data supportMSP430 Family Mixed-Signal Microcontroller Application ReportsPDF, 5.5 Mb, 档案已发布: Jan 21, 2000
MSP430 Metering Application ReportWave Digital Filtering Using the MSP430PDF, 220 Kb, 档案已发布: Sep 13, 2006
Digital filtering is an integral part of many digital signal processing algorithms. Digital filters are characterized as either recursive [infinite impulse response (IIR)] or non-recursive [finite impulse response (FIR)] filters. IIR filters require a smaller order for the same set of specifications compared to FIR filters, while FIR filters provide a linear phase property. However, IIR filters, iFSK Modulation and Demodulation With the Microcontroller MSP430PDF, 110 Kb, 档案已发布: Dec 14, 1998
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Cyclic Redundancy Code (CRC) is commonly used to determine the correctness of a data transmission or storage. This application note presents a solution to compute 16-bit and 32-bit CRCs on the ultra low-power TI MSP430 microcontroller for the bitwise algorithm (low memory, low cost) and the table-based algorithm (low MIPS, low power). Both algorithms are presented in C and MSP430 assembly. Test coMixing C and Assembler with the MSP430PDF, 168 Kb, 档案已发布: Feb 28, 2002
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Multiple MSP ultra-low-power microcontrollers offer analog-to-digital converters (ADCs) to convert physical quantities into digital numbers, a function that is widely used across numerous applications. There are times, however, when a customer design demands a higher resolution than the ADC of the selected MSP can offer. This application report, which is based on the previously-published OversamplInterfacing the MSP430 and TLC549/1549 A/D ConvertersPDF, 44 Kb, 档案已发布: Nov 16, 2000
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The TMS320C5000в„ў family of digital signal processors (DSPs) features Host Port Interface Controllers (HPI) and Direct Memory Access Controllers (DMAC) for efficient data movement without any CPU involvement. The HPI enables the DSP to interface to host processors (typically microcontrollers) bidirectionally with minimal or no external interface logic. This application report presents a hardwMSP430 Capacitive Single-Touch Sensor Design GuidePDF, 770 Kb, 档案已发布: Jan 16, 2008
This application report discusses the design of RC-type capacitive single-touch sensors using the MSP430 microcontroller. The MSP430 has some unique features that make it suitable for interfacing with capacitive-touch sensors. The RC-type method does not need special peripherals and can be implemented with all devices in the MSP430 product family. This method is also inherently low power and canProgramming a Flash-Based MSP430 Using the JTAG Interface (Rev. H)