SLAA649G October   2014  – August 2021 MSP430F2001 , MSP430F2002 , MSP430F2003 , MSP430F2011 , MSP430F2012 , MSP430F2013 , MSP430F2013-EP , MSP430F2101 , MSP430F2111 , MSP430F2112 , MSP430F2121 , MSP430F2122 , MSP430F2131 , MSP430F2132 , MSP430F2232 , MSP430F2234 , MSP430F2252 , MSP430F2254 , MSP430F2272 , MSP430F2274 , MSP430F2274-EP , MSP430F233 , MSP430F2330 , MSP430F235 , MSP430F2350 , MSP430F2370 , MSP430F2410 , MSP430F2416 , MSP430F2417 , MSP430F2418 , MSP430F2419 , MSP430F247 , MSP430F2471 , MSP430F248 , MSP430F2481 , MSP430F249 , MSP430F249-EP , MSP430F2491 , MSP430F2616 , MSP430F2617 , MSP430F2618 , MSP430F2619 , MSP430F2619S-HT , MSP430FR2032 , MSP430FR2033 , MSP430FR2110 , MSP430FR2111 , MSP430FR2153 , MSP430FR2155 , MSP430FR2310 , MSP430FR2311 , MSP430FR2353 , MSP430FR2355 , MSP430FR2433 , MSP430FR2475 , MSP430FR2476 , MSP430FR2532 , MSP430FR2533 , MSP430FR2632 , MSP430FR2633 , MSP430FR2672 , MSP430FR2673 , MSP430FR2675 , MSP430FR2676 , MSP430FR4131 , MSP430FR4132 , MSP430FR4133 , MSP430G2001 , MSP430G2101 , MSP430G2102 , MSP430G2111 , MSP430G2112 , MSP430G2121 , MSP430G2131 , MSP430G2132 , MSP430G2152 , MSP430G2153 , MSP430G2201 , MSP430G2202 , MSP430G2203 , MSP430G2210 , MSP430G2211 , MSP430G2212 , MSP430G2213 , MSP430G2221 , MSP430G2230 , MSP430G2230-EP , MSP430G2231 , MSP430G2231-EP , MSP430G2232 , MSP430G2233 , MSP430G2252 , MSP430G2253 , MSP430G2302 , MSP430G2302-EP , MSP430G2303 , MSP430G2312 , MSP430G2313 , MSP430G2332 , MSP430G2332-EP , MSP430G2333 , MSP430G2352 , MSP430G2353 , MSP430G2402 , MSP430G2403 , MSP430G2412 , MSP430G2413 , MSP430G2432 , MSP430G2433 , MSP430G2444 , MSP430G2452 , MSP430G2453 , MSP430G2513 , MSP430G2533 , MSP430G2544 , MSP430G2553 , MSP430G2744 , MSP430G2755 , MSP430G2855 , MSP430G2955 , MSP430I2020 , MSP430I2021 , MSP430I2030 , MSP430I2031 , MSP430I2040 , MSP430I2041

 

  1.   Trademarks
  2. Introduction
  3. Comparison of MSP430FR4xx and MSP430FR2xx Devices
  4. In-System Programming of Nonvolatile Memory
    1. 3.1 Ferroelectric RAM (FRAM) Overview
    2. 3.2 FRAM Cell
    3. 3.3 Protecting FRAM Using the Memory Write Protection Bit
    4. 3.4 FRAM Memory Wait States
    5. 3.5 Bootloader (BSL)
    6. 3.6 JTAG and Security
    7. 3.7 Production Programming
  5. Hardware Migration Considerations
  6. Device Calibration Information
  7. Important Device Specifications
  8. Core Architecture Considerations
    1. 7.1 Power Management Module (PMM)
      1. 7.1.1 Core LDO and LPM3.5 LDO
      2. 7.1.2 SVS
      3. 7.1.3 VREF
      4. 7.1.4 Debug in Low-Power Mode
    2. 7.2 Clock System
      1. 7.2.1 DCO Frequencies
      2. 7.2.2 FLL, REFO, and DCO Tap
      3. 7.2.3 FRAM Access at 16 MHz, ADC Clock, and Clocks-on-Demand
    3. 7.3 Operating Modes, Wake-up Times, and Reset
      1. 7.3.1 LPMx.5
      2. 7.3.2 Reset
        1. 7.3.2.1 Behavior of POR and BOR
        2. 7.3.2.2 Reset Generation
        3. 7.3.2.3 Determining the Cause of Reset
    4. 7.4 Interrupt Vectors
    5. 7.5 FRAM and the FRAM Controller
      1. 7.5.1 Flash and FRAM Overview Comparison
      2. 7.5.2 Cache Architecture
  9. Peripheral Considerations
    1. 8.1  Watchdog Timer
    2. 8.2  Ports
      1. 8.2.1 Digital Input/Output
      2. 8.2.2 Capacitive Touch I/O
    3. 8.3  Analog-to-Digital Converters
      1. 8.3.1 ADC10 to ADC
    4. 8.4  Communication Modules
      1. 8.4.1 USI to eUSCI
      2. 8.4.2 USCI to eUSCI
    5. 8.5  Timer and IR Modulation Logic
    6. 8.6  Backup Memory
    7. 8.7  Hardware Multiplier (MPY32)
    8. 8.8  RTC Counter
    9. 8.9  Interrupt Compare Controller (ICC)
    10. 8.10 LCD
    11. 8.11 Smart Analog Combo (SAC)
    12. 8.12 Comparator
  10. ROM Libraries
  11. 10Conclusion
  12. 11References
  13. 12Revision History

3.1 Ferroelectric RAM (FRAM) Overview

Unlike the F2xx family, which has flash memory integrated, the MSP430FRxx devices use FRAM nonvolatile memory. Using FRAM is very similar to using static RAM (SRAM). The introduction of FRAM as an embedded memory in a general-purpose ultra-low-power MCU was on TI's 16-bit MSP430 product line.

Some of the key attributes of FRAM are:

  • FRAM is nonvolatile, that is, it retains its contents on loss of power.
  • The embedded FRAM on MSP430 devices can be accessed (read or write) at up to a maximum speed of 8 MHz. Above 8 MHz, wait states are used when accessing FRAM.
  • Writing to FRAM and reading from FRAM require no setup or preparation such as erase before write or unlocking of control registers (unless the write protection bit is used to protect the FRAM against write access).
  • FRAM is not segmented and each bit is individually erasable, writable, and addressable.
  • FRAM does not require an erase before a write.
  • FRAM write accesses are low power because writing to FRAM does not require a charge pump.
  • FRAM writes can be performed across the full voltage range of the device.
  • FRAM write speeds can reach up to 8 MBps with a typical write speed of approximately 2 MBps. The high speed of writes is inherent to the technology and aided by the elimination of the erase bottleneck that is prevalent in other nonvolatile memory technologies [9]. In comparison, typical MSP430 flash write speed including the erase time is approximately 14 kBps [9].
  • FRAM has far greater write endurance compared to flash: practically unlimited 1015 write cycles of FRAM compared to 105 write cycles of flash.