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F29H850TU

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MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y

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F29H850TU

PRESENTACIÓN PRELIMINAR
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Detalles del producto

CPU 3 C29 Frequency (MHz) 200 Flash memory (kByte) 4864 RAM (kByte) 452 ADC type 2 16-bit SAR, 3 12-bit SAR Total processing (MIPS) 1200 Features AES, Byte addressable, Configurable logic block, EVITA-Full HSM, FPU64, HRPWM, Hardware encryption (AES/DES/SHA/MD5), Lockstep, Safety and security unit, TMU, Watchdog timer UART 6 CAN (#) 6 (CAN-FD) Sigma-delta filter 16 PWM (Ch) 36 TI functional safety category Functional Safety-Compliant Number of ADC channels 44, 54, 80 SPI 5 QEP 6 USB 0 Operating temperature range (°C) -40 to 125 Rating Catalog Communication interface CAN FD, FSI, I2C, LIN, PMBUS, SENT, SPI, UART, USB Operating system AutoSAR, FreeRTOS
CPU 3 C29 Frequency (MHz) 200 Flash memory (kByte) 4864 RAM (kByte) 452 ADC type 2 16-bit SAR, 3 12-bit SAR Total processing (MIPS) 1200 Features AES, Byte addressable, Configurable logic block, EVITA-Full HSM, FPU64, HRPWM, Hardware encryption (AES/DES/SHA/MD5), Lockstep, Safety and security unit, TMU, Watchdog timer UART 6 CAN (#) 6 (CAN-FD) Sigma-delta filter 16 PWM (Ch) 36 TI functional safety category Functional Safety-Compliant Number of ADC channels 44, 54, 80 SPI 5 QEP 6 USB 0 Operating temperature range (°C) -40 to 125 Rating Catalog Communication interface CAN FD, FSI, I2C, LIN, PMBUS, SENT, SPI, UART, USB Operating system AutoSAR, FreeRTOS
HTQFP (PTS) 176 484 mm² 22 x 22 HTQFP (RFS) 144 324 mm² 18 x 18 NFBGA (ZEX) 256 169 mm² 13 x 13

Real-time Processing

  • Three C29x 64-bit CPUs (CPU1, CPU2, CPU3) running at 200MHz
    • 2x signal chain performance versus C28x with improved pipeline
    • Split lock and lockstep operating modes
  • C29x CPU architecture
    • Byte addressability
    • High-performance real-time control with low latency
    • High-performance DSP and general-purpose processing capabilities
    • VLIW CPU executes 1 to 8 instructions in parallel
    • Fully protected pipeline
    • 8/16/32/64-bit single-cycle memory operations, up to two 64-bit memory reads and one 64-bit memory write in a single-cycle
    • IEEE 32-bit and 64-bit floating operations
    • 32-bit and 64-bit trigonometric operations
    • HW interrupt prioritization and nesting
    • 11-cycle real-time interrupt response
    • Atomic operations with memory protection
    • Multi safe island code execution managed in hardware

Memory

  • 4MB of CPU-mappable flash (ECC-protected) capable of supporting Firmware Over the Air (FOTA) with A/B swap and LFU
  • 256KB of Data-only Flash (ECC-protected)
  • 452KB of RAM (ECC-protected)
  • Dedicated 512KB Flash and 40KB RAM memories for HSM (ECC-protected)
  • Built in ECC logic for system-wide safety

Safety Peripherals

  • CPU1 and CPU2 lockstep
    • CPU1 and CPU2 splitlock mode is also available (for applications not needing functional safety or using methods like Reciprocal Comparison with multiple CPUs)
  • Logic Power-On Self-Test (LPOST)
  • Memory Power-On Self-Test (MPOST)
  • Error Signaling Module (ESM)
  • Dual-clock Comparator (DCC)
  • Waveform Analyzer and Diagnostics (WADI)
  • Context-sensitive Memory and Peripheral Protection with SSU
  • Safety Interconnect (SIC)
  • Functional Safety-Compliant targeted
    • Developed for functional safety applications
    • Documentation to aid ISO 26262 and IEC 61508 system design will be available upon production release
    • Systematic capability up to ASIL D and SIL 3 targeted
    • Hardware capability up to ASIL D and SIL 3 targeted
  • Safety-related certification
    • ISO 26262 certification up to ASIL D and IEC 61508 SIL 3 by TÜV SÜD planned

Security

  • Hardware Security Module (HSM)
    • Independently running Arm Cortex-M4 based security controller subsystem at 100MHz
    • 512KB of flash (ECC-protected)
    • 36KB of RAM (ECC-protected)
    • Secure key storage
    • Secure BOOT
    • Secure Debug
    • Dedicated 8-channel Real-Time Direct Memory Access (RTDMA) controller
    • EVITA-full support
    • FOTA with A/B swap
    • Hardware cryptographic accelerators
      • Asymmetric cryptography - RSA, ECC, SM2
      • Symmetric cryptography - AES, SM4
      • Hash operations - SHA2, HMAC, SM3
      • True Random Number Generator
  • Safety and Security Unit (SSU)
    • Advanced Real-Time Safety and Security
      • 64 Memory Access Protection Ranges per CPU
      • Up to 15 user LINKs and 7 stack pointers per CPU for hardware code isolation
      • Power-on Self-test (POST) capability
      • FOTA and LFU support with rollback control

Analog Subsystem

  • Five Analog-to-Digital Converters (ADCs)
    • Two 16-bit ADCs, 1.19MSPS each
    • Three 12-bit ADCs, 3.92MSPS each
    • Up to 80 single-ended or 16 differential inputs
    • 40 redundant input channels for flexibility
    • Separate sample-and-hold (S/H) on each ADC for simultaneous sampling
    • Hardware post-processing of conversions
    • Hardware oversampling (up to 128x) and undersampling modes, with accumulation, averaging and outlier rejection
    • Programmable delay from SOC trigger to start of conversion
    • Ten ADC Safety Checkers for comparison of conversion results across multiple ADC modules
  • 12 windowed comparators with 12-bit Digital-to-Analog Converter (DAC) references
    • Connection options for internal temperature sensor and ADC reference
  • Two 12-bit buffered DAC outputs

Control Peripherals

  • 36 Pulse Width Modulator (PWM) channels, all with high-resolution capability (HRPWM)
    • Minimum Dead-Band Logic (MINDB)
    • Illegal Combo Logic (ICL) for standard and high resolution
    • Diode Emulation (DE) support
    • Multilevel shadowing on XCMP
  • Six Enhanced Capture (eCAP) modules
    • High-resolution Capture (HRCAP) available on two of the six eCAP modules
    • Two new monitor units for edge, pulse width and period that can be coupled with ePWM strobes and trip events
    • Increased 256 multiplexed capture inputs
    • New ADC SOC generation capability
  • Six Enhanced Quadrature Encoder Pulse (eQEP) modules
  • 16 Sigma-Delta Filter Module (SDFM) input channels, 2 independent filters per channel
  • Embedded Pattern Generator (EPG)
  • Configurable Logic Block (CLB)
    • Six tiles
    • Augments existing peripheral capability
    • Supports position manager solutions

Communications Peripherals

  • EtherCAT SubordinateDevice (or SubDevice) Controller (ESC)
  • Fast Serial Interface (FSI) with four transmitters and four receivers
  • Five high-speed (up to 50MHz) SPI ports (pin-bootable)
  • Six High-Speed Universal Asynchronous Receiver/Transmitters (UARTs) (pin-bootable)
  • Two I2C interfaces (pin-bootable)
  • Two Local Interconnect Network (LIN) (supports SCI)
  • Power-Management Bus (PMBus) interface (supports I2C)
  • Six Single Edge Nibble Transmission interface (SENT)
  • Six Controller Area Networks with Flexible Data Rate (CAN FD/MCAN) (pin-bootable)

Systems Peripherals

  • External Memory Interface (EMIF) with ASRAM and SDRAM support
  • Two 10-channel Real-Time Direct Memory Access (RTDMA) controllers with MPU
  • Up to 190 usable signal pins
    • 136 General-Purpose Input/Output (GPIO) pins
    • 80 analog pins (26 AGPIOs included in GPIOs)
    • 5V fail-safe and tolerant capability on 6 GPIOs for PMBUS/I2C/SENT support
  • Peripheral Interrupt Priority and Expansion (PIPE)
  • Low-power mode (LPM) support
  • Embedded Real-time Analysis and Diagnostic (ERAD)

Clock and System Control

  • On-chip crystal oscillator
  • Windowed watchdog timer module
  • Missing clock detection circuitry
  • 1.25V core, 3.3V I/O design
    • Internal VREG for 1.25V generation
    • Brownout reset (BOR) circuit

Package Options:

  • Lead-free, green packaging
  • 256-ball New Fine Pitch Ball Grid Array (nFBGA) [ZEX suffix], 13mm x 13mm/0.8mm pitch
  • 176-pin Thermally Enhanced Thin Quad Flatpack (HTQFP) [PTS suffix], 22mm x 22mm/0.4mm pitch
  • 144-pin HTQFP [RFS suffix],18mm x 18mm/0.4mm pitch
  • 100-pin HTQFP [PZS suffix],14mm x 14mm/0.4mm pitch

Temperature

  • Ambient (TA): –40°C to 125°C

Real-time Processing

  • Three C29x 64-bit CPUs (CPU1, CPU2, CPU3) running at 200MHz
    • 2x signal chain performance versus C28x with improved pipeline
    • Split lock and lockstep operating modes
  • C29x CPU architecture
    • Byte addressability
    • High-performance real-time control with low latency
    • High-performance DSP and general-purpose processing capabilities
    • VLIW CPU executes 1 to 8 instructions in parallel
    • Fully protected pipeline
    • 8/16/32/64-bit single-cycle memory operations, up to two 64-bit memory reads and one 64-bit memory write in a single-cycle
    • IEEE 32-bit and 64-bit floating operations
    • 32-bit and 64-bit trigonometric operations
    • HW interrupt prioritization and nesting
    • 11-cycle real-time interrupt response
    • Atomic operations with memory protection
    • Multi safe island code execution managed in hardware

Memory

  • 4MB of CPU-mappable flash (ECC-protected) capable of supporting Firmware Over the Air (FOTA) with A/B swap and LFU
  • 256KB of Data-only Flash (ECC-protected)
  • 452KB of RAM (ECC-protected)
  • Dedicated 512KB Flash and 40KB RAM memories for HSM (ECC-protected)
  • Built in ECC logic for system-wide safety

Safety Peripherals

  • CPU1 and CPU2 lockstep
    • CPU1 and CPU2 splitlock mode is also available (for applications not needing functional safety or using methods like Reciprocal Comparison with multiple CPUs)
  • Logic Power-On Self-Test (LPOST)
  • Memory Power-On Self-Test (MPOST)
  • Error Signaling Module (ESM)
  • Dual-clock Comparator (DCC)
  • Waveform Analyzer and Diagnostics (WADI)
  • Context-sensitive Memory and Peripheral Protection with SSU
  • Safety Interconnect (SIC)
  • Functional Safety-Compliant targeted
    • Developed for functional safety applications
    • Documentation to aid ISO 26262 and IEC 61508 system design will be available upon production release
    • Systematic capability up to ASIL D and SIL 3 targeted
    • Hardware capability up to ASIL D and SIL 3 targeted
  • Safety-related certification
    • ISO 26262 certification up to ASIL D and IEC 61508 SIL 3 by TÜV SÜD planned

Security

  • Hardware Security Module (HSM)
    • Independently running Arm Cortex-M4 based security controller subsystem at 100MHz
    • 512KB of flash (ECC-protected)
    • 36KB of RAM (ECC-protected)
    • Secure key storage
    • Secure BOOT
    • Secure Debug
    • Dedicated 8-channel Real-Time Direct Memory Access (RTDMA) controller
    • EVITA-full support
    • FOTA with A/B swap
    • Hardware cryptographic accelerators
      • Asymmetric cryptography - RSA, ECC, SM2
      • Symmetric cryptography - AES, SM4
      • Hash operations - SHA2, HMAC, SM3
      • True Random Number Generator
  • Safety and Security Unit (SSU)
    • Advanced Real-Time Safety and Security
      • 64 Memory Access Protection Ranges per CPU
      • Up to 15 user LINKs and 7 stack pointers per CPU for hardware code isolation
      • Power-on Self-test (POST) capability
      • FOTA and LFU support with rollback control

Analog Subsystem

  • Five Analog-to-Digital Converters (ADCs)
    • Two 16-bit ADCs, 1.19MSPS each
    • Three 12-bit ADCs, 3.92MSPS each
    • Up to 80 single-ended or 16 differential inputs
    • 40 redundant input channels for flexibility
    • Separate sample-and-hold (S/H) on each ADC for simultaneous sampling
    • Hardware post-processing of conversions
    • Hardware oversampling (up to 128x) and undersampling modes, with accumulation, averaging and outlier rejection
    • Programmable delay from SOC trigger to start of conversion
    • Ten ADC Safety Checkers for comparison of conversion results across multiple ADC modules
  • 12 windowed comparators with 12-bit Digital-to-Analog Converter (DAC) references
    • Connection options for internal temperature sensor and ADC reference
  • Two 12-bit buffered DAC outputs

Control Peripherals

  • 36 Pulse Width Modulator (PWM) channels, all with high-resolution capability (HRPWM)
    • Minimum Dead-Band Logic (MINDB)
    • Illegal Combo Logic (ICL) for standard and high resolution
    • Diode Emulation (DE) support
    • Multilevel shadowing on XCMP
  • Six Enhanced Capture (eCAP) modules
    • High-resolution Capture (HRCAP) available on two of the six eCAP modules
    • Two new monitor units for edge, pulse width and period that can be coupled with ePWM strobes and trip events
    • Increased 256 multiplexed capture inputs
    • New ADC SOC generation capability
  • Six Enhanced Quadrature Encoder Pulse (eQEP) modules
  • 16 Sigma-Delta Filter Module (SDFM) input channels, 2 independent filters per channel
  • Embedded Pattern Generator (EPG)
  • Configurable Logic Block (CLB)
    • Six tiles
    • Augments existing peripheral capability
    • Supports position manager solutions

Communications Peripherals

  • EtherCAT SubordinateDevice (or SubDevice) Controller (ESC)
  • Fast Serial Interface (FSI) with four transmitters and four receivers
  • Five high-speed (up to 50MHz) SPI ports (pin-bootable)
  • Six High-Speed Universal Asynchronous Receiver/Transmitters (UARTs) (pin-bootable)
  • Two I2C interfaces (pin-bootable)
  • Two Local Interconnect Network (LIN) (supports SCI)
  • Power-Management Bus (PMBus) interface (supports I2C)
  • Six Single Edge Nibble Transmission interface (SENT)
  • Six Controller Area Networks with Flexible Data Rate (CAN FD/MCAN) (pin-bootable)

Systems Peripherals

  • External Memory Interface (EMIF) with ASRAM and SDRAM support
  • Two 10-channel Real-Time Direct Memory Access (RTDMA) controllers with MPU
  • Up to 190 usable signal pins
    • 136 General-Purpose Input/Output (GPIO) pins
    • 80 analog pins (26 AGPIOs included in GPIOs)
    • 5V fail-safe and tolerant capability on 6 GPIOs for PMBUS/I2C/SENT support
  • Peripheral Interrupt Priority and Expansion (PIPE)
  • Low-power mode (LPM) support
  • Embedded Real-time Analysis and Diagnostic (ERAD)

Clock and System Control

  • On-chip crystal oscillator
  • Windowed watchdog timer module
  • Missing clock detection circuitry
  • 1.25V core, 3.3V I/O design
    • Internal VREG for 1.25V generation
    • Brownout reset (BOR) circuit

Package Options:

  • Lead-free, green packaging
  • 256-ball New Fine Pitch Ball Grid Array (nFBGA) [ZEX suffix], 13mm x 13mm/0.8mm pitch
  • 176-pin Thermally Enhanced Thin Quad Flatpack (HTQFP) [PTS suffix], 22mm x 22mm/0.4mm pitch
  • 144-pin HTQFP [RFS suffix],18mm x 18mm/0.4mm pitch
  • 100-pin HTQFP [PZS suffix],14mm x 14mm/0.4mm pitch

Temperature

  • Ambient (TA): –40°C to 125°C

The F29H85x, F29P58x, and F29P32x are members of the C2000™ real-time microcontroller family of scalable, ultra-low latency MCUs designed for efficiency in power electronics, motor control, and beyond, including but not limited to: high power density, high switching frequencies, and supporting the use of GaN and SiC technologies. The F29 product families feature the next-generation C29 CPU core, leading the industry with 2x performance from the previous-generation C28 CPU core. The C29 core also supports byte-addressing, with data types fully compatible with other popular CPU architectures, including the Arm architecture, enabling a smooth migration for customers looking to go to market quickly. For more information, see The C29 CPU – Unrivaled Real-Time Performance with Optimized Architecture on C2000™ MCUs technical white paper.

These include such applications as:

The real-time control subsystem has up to three 200MHz C29x CPU cores (400MIPS per core, up to 1200MIPS on F29H85x). Due to the C29 CPU architecture and tightly coupled peripherals (PWM, ADC, CMPSS), we see better performance with a 200MHz C29 core versus our competition running at higher CPU clock speed for certain applications – backed by customer benchmarks.

Many features are included to support a system-level ASIL D functional safety solution. The C29x CPU1 and CPU2 cores can be put in lockstep for detection of permanent and transient faults. Logic Power-On Self-Test (LPOST) and Memory Power-On Self-Test (MPOST) provide start-up detection of latent faults. Safe interconnects provide fault detection between the CPU and the peripherals. The ADC safety checker compares ADC conversion results from multiple ADC modules without additional CPU cycles. The Waveform Analyzer and Diagnostic (WADI) can monitor multiple signals for proper operation and take action to ensure a safe state is maintained. The device architecture features a Safe Interconnect (SIC) for end-to-end code and data safety, with CPU-based ECC protection for all memories and peripheral endpoints.

Hardware Security Manager (HSM) provides EVITA-full security support. Features include Secure Boot, secure storage and keyring support, secure debug authentication, and cryptographic accelerator engines. The HSM enables secure key and code provisioning in untrusted factory environments, and supports Firmware-Over-The-Air updates of HSM and host application firmware, with A/B swap capability and rollback control.

SSU (Safety and Security unit) enables superior run-time safety and security features. This feature can be used create safety isolation (Freedom From Interference) among the threads running on same CPU or different CPUs. The SSU features a context-sensitive MPU mechanism that automatically switches access permissions in hardware based on currently executing thread or task. This eliminates software overhead, enabling real-time code performance without compromising system safety. The SSU provides multi-user debug authentication, and also supports Live Firmware Update (LFU) and FOTA fpr application firmware updates with A/B swap and rollback control. For more information, see the Implementing Run-Time Safety and Security With the C29x Safety and Security Unit Application Note.

High-performance analog blocks are tightly integrated with the processing and control units to provide optimal real-time signal chain performance. Two 16-bit Analog-to-Digital Converters (ADC) and three 12-bit ADCs have up to 80 analog channels as well as an integrated post-processing block and hardware oversampling. Two 12-bit buffered DACs and twenty-four comparator channels are available.

Thirty-six frequency-independent PWMs, all with high-resolution capability, enable control of multiple power stages, from 3-phase inverters to advanced multilevel power topologies. The PWMs have been enhanced with Minimum Dead-Band Logic (MINDL), Diode Emulation (DE), and Illegal Combo Logic (ICL) features.

The Configurable Logic Block (CLB) allows the user to add custom logic and potentially integrate FPGA-like functions into the C2000 real-time MCU.

An EtherCAT SubDevice Controller and other industry-standard protocols like CAN FD are available on this device. The Fast Serial Interface (FSI) enables up to 200Mbps of robust communications across an isolation boundary.

Want to learn more about features that make C2000 MCUs the right choice for your real-time control system? Check out The Essential Guide for Developing With C2000™ Real-Time Microcontrollers and visit the C2000 real-time microcontrollers page.

The Getting Started With C2000™ Real-Time Control Microcontrollers (MCUs) Getting Started Guide covers all aspects of development with C2000 devices from hardware to support resources. In addition to key reference documents, each section provides relevant links and resources to further expand on the information covered.

Ready to get started? Check out the F29H85X-SOM-EVM evaluation board, and download the F29-SDK Foundational Software Development Kit (SDK) for F29 real-time MCUs.

The F29H85x, F29P58x, and F29P32x are members of the C2000™ real-time microcontroller family of scalable, ultra-low latency MCUs designed for efficiency in power electronics, motor control, and beyond, including but not limited to: high power density, high switching frequencies, and supporting the use of GaN and SiC technologies. The F29 product families feature the next-generation C29 CPU core, leading the industry with 2x performance from the previous-generation C28 CPU core. The C29 core also supports byte-addressing, with data types fully compatible with other popular CPU architectures, including the Arm architecture, enabling a smooth migration for customers looking to go to market quickly. For more information, see The C29 CPU – Unrivaled Real-Time Performance with Optimized Architecture on C2000™ MCUs technical white paper.

These include such applications as:

The real-time control subsystem has up to three 200MHz C29x CPU cores (400MIPS per core, up to 1200MIPS on F29H85x). Due to the C29 CPU architecture and tightly coupled peripherals (PWM, ADC, CMPSS), we see better performance with a 200MHz C29 core versus our competition running at higher CPU clock speed for certain applications – backed by customer benchmarks.

Many features are included to support a system-level ASIL D functional safety solution. The C29x CPU1 and CPU2 cores can be put in lockstep for detection of permanent and transient faults. Logic Power-On Self-Test (LPOST) and Memory Power-On Self-Test (MPOST) provide start-up detection of latent faults. Safe interconnects provide fault detection between the CPU and the peripherals. The ADC safety checker compares ADC conversion results from multiple ADC modules without additional CPU cycles. The Waveform Analyzer and Diagnostic (WADI) can monitor multiple signals for proper operation and take action to ensure a safe state is maintained. The device architecture features a Safe Interconnect (SIC) for end-to-end code and data safety, with CPU-based ECC protection for all memories and peripheral endpoints.

Hardware Security Manager (HSM) provides EVITA-full security support. Features include Secure Boot, secure storage and keyring support, secure debug authentication, and cryptographic accelerator engines. The HSM enables secure key and code provisioning in untrusted factory environments, and supports Firmware-Over-The-Air updates of HSM and host application firmware, with A/B swap capability and rollback control.

SSU (Safety and Security unit) enables superior run-time safety and security features. This feature can be used create safety isolation (Freedom From Interference) among the threads running on same CPU or different CPUs. The SSU features a context-sensitive MPU mechanism that automatically switches access permissions in hardware based on currently executing thread or task. This eliminates software overhead, enabling real-time code performance without compromising system safety. The SSU provides multi-user debug authentication, and also supports Live Firmware Update (LFU) and FOTA fpr application firmware updates with A/B swap and rollback control. For more information, see the Implementing Run-Time Safety and Security With the C29x Safety and Security Unit Application Note.

High-performance analog blocks are tightly integrated with the processing and control units to provide optimal real-time signal chain performance. Two 16-bit Analog-to-Digital Converters (ADC) and three 12-bit ADCs have up to 80 analog channels as well as an integrated post-processing block and hardware oversampling. Two 12-bit buffered DACs and twenty-four comparator channels are available.

Thirty-six frequency-independent PWMs, all with high-resolution capability, enable control of multiple power stages, from 3-phase inverters to advanced multilevel power topologies. The PWMs have been enhanced with Minimum Dead-Band Logic (MINDL), Diode Emulation (DE), and Illegal Combo Logic (ICL) features.

The Configurable Logic Block (CLB) allows the user to add custom logic and potentially integrate FPGA-like functions into the C2000 real-time MCU.

An EtherCAT SubDevice Controller and other industry-standard protocols like CAN FD are available on this device. The Fast Serial Interface (FSI) enables up to 200Mbps of robust communications across an isolation boundary.

Want to learn more about features that make C2000 MCUs the right choice for your real-time control system? Check out The Essential Guide for Developing With C2000™ Real-Time Microcontrollers and visit the C2000 real-time microcontrollers page.

The Getting Started With C2000™ Real-Time Control Microcontrollers (MCUs) Getting Started Guide covers all aspects of development with C2000 devices from hardware to support resources. In addition to key reference documents, each section provides relevant links and resources to further expand on the information covered.

Ready to get started? Check out the F29H85X-SOM-EVM evaluation board, and download the F29-SDK Foundational Software Development Kit (SDK) for F29 real-time MCUs.
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* Data sheet F29H85x, F29P58x, and F29P32x Real-Time Microcontrollers datasheet (Rev. B) PDF | HTML 30 sep 2025
* Errata F29H85x, F29P58x, and F29P32x Real-Time MCUs Silicon Errata (Rev. B) PDF | HTML 01 oct 2025
* User guide F29H85x and F29P58x Real-Time Microcontrollers Technical Reference Manual PDF | HTML 08 nov 2024
Application note Implementing Run-Time Safety and Security With the C29x Safety and Security Unit (Rev. A) PDF | HTML 03 oct 2025
Application note F29x Error Handling and Debug Guide PDF | HTML 11 sep 2025
User guide F29x Motor Control SDK Universal Project and Lab PDF | HTML 20 ago 2025
Application note MCU Control Center Tool Developer's Guide PDF | HTML 04 ago 2025
Application note MCU Signal Sight Tool Developer's Guide PDF | HTML 01 ago 2025
User guide F29H85x Flash API User's Guide (Rev. A) PDF | HTML 01 jul 2025
Application note Firmware-Over-The-Air Upgrade Example for F29H85x PDF | HTML 25 jun 2025
EVM User's guide F29H85X-SOM-EVM F29H85X controlSOM Evaluation Board User’s Guide (Rev. D) PDF | HTML 09 jun 2025
User guide F29H85x MCAL User Guide 09 may 2025
User guide C29 Software Optimization Guide (Rev. A) PDF | HTML 30 abr 2025
Application note C2000-IDE Assist Tool Migration Feature Guide PDF | HTML 23 abr 2025
Product overview Industrial Functional Safety for C2000™ Real-Time Microcontrollers (Rev. F) 23 abr 2025
User guide C29x CPU Reference Guide (Rev. A) PDF | HTML 28 mar 2025
Application brief How to Debug Interrupt Abnormalities PDF | HTML 25 feb 2025
Application brief C2000 F29H85x and F29P58x Real-Time Microcontrollers PDF | HTML 18 feb 2025
User guide TI C29x clang compiler tools user's guide 06 feb 2025
Application note C2000 IDE Assist Tool Features Guide (Rev. A) PDF | HTML 29 ene 2025
Application note EEPROM Emulation Driver Guide for C29x PDF | HTML 09 ene 2025
Application note DLT Developer's Guide With Tooling PDF | HTML 23 dic 2024
Application note Serial Flash Programming of F29H85x™ PDF | HTML 23 dic 2024
User guide Migration Between TMS320F28P65x and TMS320F29H85x PDF | HTML 15 nov 2024
White paper Enabling Cybersecurity for High Performance Real-Time Control Systems with C2000™ F29x Microcontrollers PDF | HTML 08 nov 2024
Application brief Optimize EPS System with C2000 F29 MCU PDF | HTML 08 nov 2024
Application brief How MCUs Built With Innovative C29 Cores Increase Real-Time Performance in High-Voltage Systems PDF | HTML 05 nov 2024
User guide Application Software Migration to the C29 CPU User's Guide PDF | HTML 24 oct 2024
White paper The C29 CPU – Unrivaled Real-Time Performance with Optimized Architecture on C2000 MCUs PDF | HTML 14 oct 2024
Application brief Discrete Power Design for C2000™ PDF | HTML 15 ago 2024
Application note Development Tool Versions for C2000™ Support (Rev. A) PDF | HTML 26 jun 2024
Product overview Implementing IEC 60730 / UL 1998 Compliance for C2000 Real-Time Microcontrollers (Rev. A) PDF | HTML 25 jun 2024
Application note Obtain UL/IEC 60730-1/60335-1 Class B Certification Based on C2000™ MCU Diagnostic Library in Appliances PDF | HTML 30 may 2024
Application note Power Supply and Monitoring Solution for C2000 MCU Automotive Applications PDF | HTML 17 abr 2024
Application note CAN Flash Programming of C2000™ Microcontrollers (Rev. A) PDF | HTML 15 abr 2024
Application note Clock Edge Delay Compensation With Isolated Modulators Digital Interface to MCUs (Rev. A) PDF | HTML 12 ene 2024
Application note EEPROM Emulation for Generation 3 C2000 Real-Time Controllers (Rev. B) PDF | HTML 16 nov 2023
White paper Achieving High Efficiency and Enabling Integration in EV Powertrain Subsystems (Rev. A) PDF | HTML 17 jul 2023
Application note CRC Engines in C2000 Devices (Rev. A) PDF | HTML 01 may 2023
Application note ADC Input Circuit Evaluation for C2000 MCUs (using TINA-TI simulation tool) (Rev. A) PDF | HTML 24 mar 2023
Application note ADC Input Circuit Evaluation for C2000 Real-Time MCUs (using PSPICE-FOR-TI) PDF | HTML 24 mar 2023
Application note Charge-Sharing Driving Circuits for C2000 ADCs (using PSPICE-FOR-TI) (Rev. A) PDF | HTML 24 mar 2023
Application note Charge-Sharing Driving Circuits for C2000 ADCs (using TINA-TI simulation tool) (Rev. A) PDF | HTML 24 mar 2023
Application note Methods for Mitigating ADC Memory Cross-Talk (Rev. A) PDF | HTML 24 mar 2023
Application note Using SMI of C2000 EtherCAT Slave Controller for Ethernet PHY Configuration PDF | HTML 27 feb 2023
Application note C2000 ePWM Developer’s Guide (Rev. A) PDF | HTML 24 feb 2023
Application note How to Implement Custom Serial Interfaces Using Configurable Logic Block (CLB) PDF | HTML 03 feb 2023
Application note C2000 SysConfig Linker Command Tool PDF | HTML 26 ene 2023
Application note Using the Fast Serial Interface (FSI) With Multiple Devices in an Application (Rev. E) PDF | HTML 25 ene 2023
Application note Diagnosing Delta-Sigma Modulator Bitstream Using C2000™ Configurable Logic Block PDF | HTML 19 dic 2022
User guide Getting Started With C2000™ Real-Time Control Microcontrollers (MCUs) (Rev. C) PDF | HTML 29 jun 2022
Application note Implement three-phase interleaved LLC on C2000 Type-4 PWM PDF | HTML 30 mar 2022
Application note The Essential Guide for Developing With C2000 Real-Time Microcontrollers (Rev. F) PDF | HTML 03 mar 2022
Application note Real-Time Benchmarks Showcasing C2000™ Control MCU's Optimized Signal Chain (Rev. A) PDF | HTML 15 dic 2021
Application note Achieve Delayed Protection for Three-Level Inverter With Type 4 EPWM PDF | HTML 29 oct 2021
Application note C2000 SysConfig PDF | HTML 20 oct 2021
Application note Getting Started with the MCAN (CAN FD) Module PDF | HTML 20 oct 2021
Application note Achieve Delayed Protection for Three-Level Inverter With CLB PDF | HTML 28 jun 2021
Application note Programming Examples for the DCAN Module (Rev. A) PDF | HTML 20 may 2021
Application note Leverage New Type ePWM Features for Multiple Phase Control PDF | HTML 11 may 2021
Application note CRM/ZVS PFC Implementation Based on C2000 Type-4 PWM Module PDF | HTML 18 feb 2021
White paper Achieve Power-Dense and Efficient Digital Power Systems by Combining TI GaN FETs 05 ene 2021
More literature Maximize density, power, and reliability with TI GaN and C2000™ real-time MCUs 15 dic 2020
Application note C2000™ Unique Device Number (Rev. B) PDF | HTML 17 sep 2020
Application note Secure BOOT On C2000 Device 21 jul 2020
Application note How to Migrate Custom Logic From an FPGA/CPLD to C2000 Microcontrollers (Rev. A) 15 jun 2020
Application note EtherCAT Based Connected Servo Drive using Fast Current Loop on PMSM (Rev. B) PDF | HTML 19 feb 2020
White paper Distributed Power Control Architecture w/ C2000 MCUs Over Fast Serial Interface PDF | HTML 14 feb 2020
E-book E-book: An engineer’s guide to industrial robot designs 12 feb 2020
Application note Configurable Error Generator for Controller Area Network PDF | HTML 19 dic 2019
Application note Leveraging High Resolution Capture (HRCAP) for Single Wire Data Transfer PDF | HTML 28 ago 2019
Application note Fast Integer Division – A Differentiated Offering From C2000 Product Family PDF | HTML 14 jun 2019
Application note Calculating Useful Lifetimes of Embedded Processors (Rev. B) PDF | HTML 07 may 2019
Application note Embedded Real-Time Analysis and Response for Control Applications PDF | HTML 29 mar 2019
Application note Designing With The C2000 Configurable Logic Block 05 feb 2019
Application note MSL Ratings and Reflow Profiles (Rev. A) 13 dic 2018
Application note Fast Serial Interface (FSI) Skew Compensation 08 nov 2018
White paper Maximizing power for Level 3 EV charging stations 12 jun 2018
Application note Calculating FIT for a Mission Profile 24 mar 2015
User guide C2000 Real-Time Control Peripheral Reference Guide (Rev. U) PDF | HTML 30 ago 2001

Diseño y desarrollo

Para conocer los términos adicionales o los recursos necesarios, haga clic en cualquier título de abajo para ver la página de detalles cuando esté disponible.

Placa de evaluación

F29H85X-SOM-EVM — Módulo de evaluación controlSOM F29H85x

Para evaluar el F29H85X-SOM-EVM, se debe comprar por separado la sonda de depuración XDS110ISO-EVM.

El HSEC180ADAPEVM y el TMDSHSECDOCK se pueden adquirir opcionalmente por separado por retrocompatibilidad con plataformas basadas en controlCARD.

El F29H85X-SOM-EVM es una placa de evaluación y (...)

Guía del usuario: PDF | HTML
No disponible en TI.com
Placa de evaluación

HSEC180ADAPEVM — Placa adaptadora HSEC180 para plataformas basadas en sistemas en módulo (SOM)

Este módulo de evaluación es un adaptador de tarjeta de borde de alta velocidad (HSEC) de 180 pines para plataformas de sistemas en módulo C2000™ de TI, lo que permite que las plataformas basadas en SOM sean compatibles con versiones anteriores con EVM basados en HSEC C2000. El HSEC180ADAPEVM (...)

Guía del usuario: PDF | HTML
No disponible en TI.com
Placa de evaluación

LAUNCHXL-F29H85X — C2000™ real-time MCU F29H85x LaunchPad™ development kit

The LAUNCHXL-F29H85X is a low-cost development board for the Texas Instruments C2000™ Real-Time Microcontroller series of F29H85x devices. The LAUNCHXL-F29H85X is designed around the F29H850TU real-time microcontroller (MCU) and highlights the control, analog, and communications peripherals, as (...)

Guía del usuario: PDF | HTML
No disponible en TI.com
Placa de evaluación

XDS110ISO-EVM — Módulo de evaluación de complemento aislado XDS110 para los controlSOM de C2000 y Sitara™

La placa de complemento aislada XDS110 es un módulo de evaluación de depuración y programación flash en tiempo real para los controlSOM de C2000 y Sitara. Se puede conectar a los controlSOM de C2000 y Sitara a través de un conector no aislado de 120 pines o a través de un conector de 16 pines (...)
Guía del usuario: PDF | HTML
No disponible en TI.com
Tarjeta secundaria

TMDSHSECDOCK — Estación de acoplamiento de la placa de controlCARD HSEC180

TMDSHSECDOCK es una placa base que proporciona acceso mediante pines a las señales clave en controlCARD compatibles basados en HSEC180. Un área de las unidades de placa de base está disponible para la creación rápida de prototipos. La alimentación de la placa se puede realizar mediante el cable USB (...)

Guía del usuario: PDF | HTML
No disponible en TI.com
Kit de desarrollo de software (SDK)

F29H85X-SDK Core software development kit for F29H85x real-time MCUs

The F29x SDKs support the C29x cpu based family of real time MCUs. Together, these SDKs provide comprehensive software packages for the development of high-performance real-time control applications. The SDKs enable easy integration of host functionality together with the control, safety and (...)

Productos y hardware compatibles

Productos y hardware compatibles

Productos
Microcontroladores en tiempo real C2000
F29H850TU MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y F29H859TU-Q1 MCU C2000™ automotriz de 64 bits con tri-core de 200 MHz C29x, lockstep, cumplimiento de seguridad f
Desarrollo de hardware
Placa de evaluación
F29H85X-SOM-EVM Módulo de evaluación controlSOM F29H85x
Examinar Opciones de descarga
Kit de desarrollo de software (SDK)

F29H85X-TIFS-SDK F29H85x foundational security software

The F29x SDKs support the C29x cpu based family of real time MCUs. Together, these SDKs provide comprehensive software packages for the development of high-performance real-time control applications. The SDKs enable easy integration of host functionality together with the control, safety and (...)

Productos y hardware compatibles

Productos y hardware compatibles

Productos
Microcontroladores en tiempo real C2000
F29H850TU MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y F29H859TU-Q1 MCU C2000™ automotriz de 64 bits con tri-core de 200 MHz C29x, lockstep, cumplimiento de seguridad f
Desarrollo de hardware
Placa de evaluación
F29H85X-SOM-EVM Módulo de evaluación controlSOM F29H85x
Software
Kit de desarrollo de software (SDK)
F29-SDK Kit de desarrollo de software básicos (SDK) para MCU en tiempo real F29
Solicitar
Kit de desarrollo de software (SDK)

F29X-MOTOR-CONTROL-SDK Motor Control SDK for F29x devices

The F29x SDKs support the C29x cpu based family of real time MCUs. Together, these SDKs provide comprehensive software packages for the development of high-performance real-time control applications. The SDKs enable easy integration of host functionality together with the control, safety and (...)

Productos y hardware compatibles

Productos y hardware compatibles

Productos
Microcontroladores en tiempo real C2000
F29H850TU MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y F29H859TU-Q1 MCU C2000™ automotriz de 64 bits con tri-core de 200 MHz C29x, lockstep, cumplimiento de seguridad f
Desarrollo de hardware
Tarjeta secundaria
BOOSTXL-3PHGANINV Inversor trifásico de 48 V con módulo de evaluación de detección de corriente de fase de motor en lí
Placa de evaluación
BOOSTXL-LMG2100-MD Módulo de evaluación boost LMG2100 BP-AMC0106-LMG-MD BP-AMC0106-LMG-MD evaluation module DAC128S085EVM Módulo de evaluación del convertidor digital a analógico 12 bits y 8 canales
Examinar Opciones de descarga
Firmware

USIT-3P-SECIC-PQC — Firmware de algoritmos Uni-Sentry SecIC-PQC

Las soluciones de seguridad de Uni-Sentry adoptan algoritmos PQC capaces de resistir las amenazas de descifrado planteadas por los ordenadores cuánticos a los algoritmos criptográficos tradicionales. El firmware del PQC está cooptimizado con el Módulo de Seguridad de Hardware (HSM), aprovechando la (...)
Desde: Shanghai Uni-Sentry Intelligent Technology Co., LTD
View Options
IDE, configuración, compilador o depurador

CCSTUDIO Code Composer Studio™ integrated development environment (IDE)

Code Composer Studio is an integrated development environment (IDE) for TI's microcontrollers and processors. It is comprised of a rich suite of tools used to build, debug, analyze and optimize embedded applications. Code Composer Studio is available across Windows®, Linux® and macOS® platforms.

(...)

Productos y hardware compatibles

Productos y hardware compatibles

Este recurso de diseño es compatible con la mayoría de los productos de estas categorías.

Revise la página de detalles del producto para verificar la compatibilidad.
Iniciar Opciones de descarga
Capacitación en línea

C29X-ACADEMY C29X-ACADEMY

The C29x Academy is a great resource for developers to learn about C29-based C2000 real-time microcontrollers. The Academy delivers informational training modules as well as hands-on lab exercises that span a variety of topics.
Productos y hardware compatibles

Productos y hardware compatibles

Productos
Microcontroladores en tiempo real C2000
F29H850TU MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y F29H859TU-Q1 MCU C2000™ automotriz de 64 bits con tri-core de 200 MHz C29x, lockstep, cumplimiento de seguridad f
Desarrollo de hardware
Placa de evaluación
F29H85X-SOM-EVM Módulo de evaluación controlSOM F29H85x LAUNCHXL-F29H85X C2000™ real-time MCU F29H85x LaunchPad™ development kit
Software
Kit de desarrollo de software (SDK)
F29-SDK Kit de desarrollo de software básicos (SDK) para MCU en tiempo real F29
Examinar
Herramienta de programación de software

UNIFLASH UniFlash for most TI microcontrollers (MCUs) and mmWave sensors

UniFlash is a software tool for programming on-chip flash on TI microcontrollers and wireless connectivity devices and on-board flash for TI processors. UniFlash provides both graphical and command-line interfaces.

UniFlash can be run from the cloud on the TI Developer Zone or downloaded and used (...)

Productos y hardware compatibles

Productos y hardware compatibles

Productos
Microcontroladores en tiempo real C2000
F29H850TU MCU C2000™ de 64 bits con tri-core C29x de 200 MHz, lockstep, cumplimiento de seguridad funcional y F29H859TU-Q1 MCU C2000™ automotriz de 64 bits con tri-core de 200 MHz C29x, lockstep, cumplimiento de seguridad f TMS320F2800132 Unidad de microcontrolador C2000™ de 32 bits con 100 MHz, memoria flash de 64 kB, FPU, TMU, seis PWM TMS320F2800133 MCU C2000™ de 32 bits con 120 MHz, 64 KB de memoria flash, FPU y TMU TMS320F2800135 MCU C2000™ de 32 bits con 120 MHz, 128 KB de memoria flash, FPU y TMU TMS320F2800137 MCU C2000™ de 32 bits con 120 MHz, 256 KB de memoria flash, FPU y TMU TMS320F2800152-Q1 MCU C2000™ de 32 bits para automoción con 100 MHz, memoria flash de 64 KB con CAN-FD, lockstep ASIL  TMS320F2800153-Q1 MCU C2000™ de 32 bits para automoción con 120 MHz, memoria flash de 64 KB con HRPWM, CAN-FD, lockste TMS320F2800154-Q1 MCU C2000™ de 32 bits para automoción con 100 MHz, memoria flash de 128 KB con CAN-FD, lockstep ASIL TMS320F2800155 MCU C2000™ de 32 bits con 120 MHz, Flash de 128 KB con HRPWM, CAN-FD TMS320F2800155-Q1 MCU C2000™ de 32 bits para automoción con 120 MHz, memoria flash de 128 KB con HRPWM, CAN-FD, lockst TMS320F2800156-Q1 MCU C2000™ de 32 bits para automoción con 100 MHz, memoria flash de 256 KB con CAN-FD, lockstep ASIL TMS320F2800157 MCU C2000™ de 32 bits con 120 MHz, Flash de 256 KB con HRPWM, CAN-FD TMS320F2800157-Q1 MCU C2000™ de 32 bits para automoción con 120 MHz, memoria flash de 256 KB con HRPWM, CAN-FD, lockst TMS320F28P550SG MCU C2000™ de 32 bits con C28x + CLA de 150 MHz y 512 KB de memoria flash, 5 ADC, CLB, AES y NPU< TMS320F28P550SJ MCU C2000™ de 32 bits con flash de 1.1 MB a 150 MHz C28x + CLA, cinco ADC, CLB, AES y NPU TMS320F28P559SG-Q1 MCU C2000™ de 32 bits automotriz con 150 MHz 512 KB flash C28x + CLA, cinco ADC, CLB, AES y NPU.< TMS320F28P559SJ-Q1 MCU automotriz, C2000™ de 32 bits con 150 MHz, 1.1 MB flash C28x + CLA, cinco ADC, CLB, AES y NPU TMS320F28P650DH MCU C2000 de 32 bits, 600 MIPS, 2xC28x + 1xCLA CPU, FPU64, 768 kB de memoria flash, 16 b ADC TMS320F28P650DK Microcontrolador C2000™ de 32 bits, 2 CPU C28x+CLA, paso de bloqueo, flash de 1.28 MB, ADC de 16 b, TMS320F28P650SH MCU C2000 de 32 bits, 400 MIPS, 1xC28x + 1xCLA CPU, FPU64, 768 kB de memoria flash, 16 b ADC TMS320F28P650SK MCU C2000 de 32 bits, 400 MIPS, 1xC28x + 1xCLA CPU, FPU64, 1.28 MB de memoria flash, 16 b ADC, Ether
Procesadores basados en ARM®
AM4372 Procesador Sitara: Arm Cortex-A9 AM4376 Procesador Sitara: Arm Cortex-A9, PRU-ICSS AM4377 Procesador Sitara: Arm Cortex-A9, PRU-ICSS, EtherCAT AM4378 Procesador Sitara: Arm Cortex-A9, PRU-ICSS, gráficos 3D AM4379 Procesador Sitara: Arm Cortex-A9, PRU-ICSS, EtherCAT, gráficos 3D AM5716 Procesador Sitara: Arm Cortex-A15 y DSP AM5718 Procesador Sitara: ARM Cortex-A15 y DSP, multimedia AM5718-HIREL Procesadores AM5718-HIREL Sitara™ Revisión de Silicon 2.0 AM5726 Procesador Sitara: Arm Cortex-A15 doble y DSP doble AM5728 Procesador Sitara: Arm Cortex-A15 doble y DSP doble, multimedia AM5729 Procesador Sitara AM5746 Procesador Sitara: arm Cortex-A15 doble y DSP doble, ECC en DDR y arranque seguro AM5748 Procesador Sitara: arm Cortex-A15 doble y DSP doble, multimedia, ECC en DDR y arranque seguro AM5749 Procesador Sitara: Arm Cortex-A15 doble y DSP doble, multimedia, ECC en DDR, arranque seguro, aprend AM6526 Procesador Arm® Cortex®-A53 doble y Arm Cortex-R5F Sitara™ doble con gigabit PRU-ICSS AM6528 Procesador Sitara: Arm Cortex-A53 doble y Arm Cortex-R5F doble, Gigabit PRU-ICSS, gráficos 3D AM6546 Procesador Arm® Cortex®-A53 cuádruple y Arm Cortex-R5F Sitara™ doble con gigabit PRU-ICSS AM6548 Procesador Arm® Cortex®-A53 cuádruple y Arm Cortex-R5F Sitara™ doble con gigabit PRU-ICSS y gráficos
MCU Arm Cortex-M0+
MSPM0C1103 MCU Arm® Cortex®-M0+ de 24 MHz con memoria flash de 8 KB, 1 KB de SRAM y ADC de 12 bits MSPM0C1103-Q1 MCU Arm® Cortex®-M0+ de 24 MHz con memoria flash de 8 KB, 1 KB de SRAM, ADC de 12 bits y LIN para au MSPM0C1104 MCU Arm® Cortex®-M0+ de 24 MHz con memoria flash de 16 KB, 1 KB de SRAM y ADC de 12 bits MSPM0C1104-Q1 MCU Arm® Cortex®-M0+ de 24 MHz con memoria flash de 16 KB, 1 KB de SRAM, ADC de 12 bits y LIN para a MSPM0C1105 Microcontrolador Arm® Cortex®-M0+ de 32 MHz, con flash de 32 kB, SRAM de 8 kB, ADC de 12 bits, compa MSPM0C1106 Microcontrolador Arm® Cortex®-M0+ de 32 MHz, con flash de 64 kB, SRAM de 8 kB, ADC de 12 bits, compa MSPM0C1106-Q1 Microcontrolador Arm® Cortex®-M0+ de 32 MHz, para uso automotriz, con 64 kB de memoria flash, 8 kB d MSPM0G1105 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps y amplificador operacional con SRAM MSPM0G1106 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps y amplificador operacional con SRAM de MSPM0G1107 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps y amplificador operacional con SRAM MSPM0G1505 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC de 12 bits, 3 COMP, 2 OPA y MATHACL, y memor MSPM0G1506 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC de 12 bits, 3 COMP, 2 OPA y MATHACL, y memor MSPM0G1507 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC de 12 bits, 3 COMP, 2 OPA y MATHACL, y memor MSPM0G1518 MCU ARM® Cortex®-M0+ de 80 MHz con memoria flash de doble banco de 256 KB, SRAM de 128 KB, 2 ADC, DA MSPM0G1519 MCU ARM® Cortex®-M0+ de 80 MHz con memoria flash de doble banco de 512 KB, SRAM de 128 KB, 2 ADC, DA MSPM0G3105 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps, amplificador operacional y CAN-FD con MSPM0G3105-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con 2 ADC 12 bits y 4 Msps, amplificador operacional y CAN MSPM0G3106 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps, amplificador operacional y CAN-FD con MSPM0G3106-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con 2 ADC 12 bits y 4 Msps, amplificador operacional y CAN MSPM0G3107 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 12 bits y 4 Msps, amplificador operacional y CAN-FD con MSPM0G3107-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con 2 ADC 12 bits y 4 Msps, amplificador operacional y CAN MSPM0G3505 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC, 3 COMP, 2 OPA, CAN-FD, MATHACL con SRAM MSPM0G3505-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con ADC, DAC, COMP, OPA, CAN-FD, MATHACL con SRAM de 16KB MSPM0G3506 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC, 3 COMP, 2 OPA, CAN-FD, MATHACL con SRAM de MSPM0G3506-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con ADC, DAC, COMP, OPA, CAN-FD, MATHACL con SRAM de 32KB MSPM0G3507 MCU Arm® Cortex® M0+ de 80 MHz con 2 ADC de 4 Msps, DAC, 3 COMP, 2 OPA, CAN-FD, MATHACL con SRAM de MSPM0G3507-Q1 MCU automotriz Arm® Cortex® M0+ de 80 MHz con ADC, DAC, COMP, OPA, CAN-FD, MATHACL con SRAM de 32KB MSPM0G3518 MCU ARM® Cortex®-M0+ de 80 MHz con memoria flash de doble banco de 256 KB, SRAM de 128 KB, 2 CAN-FD, MSPM0G3518-Q1 MCU ARM® Cortex®-M0+ de 80 MHz automotriz con 256 kB flash, 128 kB SRAM, 2 CAN, 2 ADC, DAC, COMP MSPM0G3519 MCU ARM® Cortex®-M0+ de 80 MHz con memoria flash de doble banco de 512 KB, SRAM de 128 KB, 2 CAN-FD, MSPM0G3519-Q1 MCU ARM® Cortex®-M0+ de 80 MHz automotriz con 512 kB flash, 128 kB SRAM, 2 CAN, 2 ADC, DAC, COMP MSPM0G3529-Q1 MCU ARM® Cortex®-M0+ de 80 MHz para uso automotriz con memoria flash de 512 kB, 128 kB de SRAM, d MSPM0H3216 MCU Arm® Cortex®-M0+ de 32 MHz con alimentación de 5 V, memoria flash de 64 KB, 8 KB de SRAM y AD MSPM0H3216-Q1 MCU Arm® Cortex®-M0+ de 32 MHz para uso automotriz con alimentación de 5 V, memoria flash de 64 K MSPM0L1105 MCU Arm® Cortex®-M0+ a 32 MHz de memoria flash de 32 KB, 4 KB de SRAM, ADC de 12 bits MSPM0L1106 MCU Arm® Cortex®-M0+ a 32 MHz de memoria flash de 64 KB, 4 KB de SRAM, ADC de 12 bits MSPM0L1116 Microcontrolador Arm® Cortex®-M0+ de 32 MHz con dual-bank flash de 64KB, SRAM de 16KB, ADC de 12-bit MSPM0L1117 Microcontrolador Arm® Cortex®-M0+ de 32 MHz con dual-bank flash de 128KB, SRAM de 16KB, ADC de 12-bi MSPM0L1227 MCU Arm® Cortex®-M0+ de 32 MHz con memoria flash de doble banco de 128 KB, SRAM de 32 KB, ADC de 12 MSPM0L1227-Q1 Automotive 32MHz Arm® Cortex®-M0+ MCU with 128KB dual-bank flash, 32KB SRAM, ADC, COMP, LCD, VBAT MSPM0L1228 MCU Arm® Cortex®-M0+ de 32 MHz con memoria flash de doble banco de 256 KB, SRAM de 32 KB, ADC de 12 MSPM0L1228-Q1 Automotive 32MHz Arm® Cortex®-M0+ MCU with 256KB dual-bank flash, 32KB SRAM, ADC, COMP, LCD, VBAT MSPM0L1303 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 8 KB, 2 KB de SRAM, ADC de 12 bits, comparador, O MSPM0L1304 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 16 KB, 2 KB de SRAM, ADC de 12 bits, comparador, MSPM0L1304-Q1 Arm® Cortex®-M0+ de 32 Mhz auto. con memoria flash de 16 KB, 2 KB de RAM, ADC de 12 bits, OPA y LIN MSPM0L1305 MCU Arm® Cortex®-M0+ de 32 MHz con flash de 32 KB, 4 KB de SRAM, ADC de 12 bits, comparador y OPA MSPM0L1305-Q1 Arm® Cortex®-M0+ de 32 Mhz automotriz con memoria flash de 32 kB, 4 kB de RAM, convertidor analógico MSPM0L1306 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 64 KB, 4 KB de SRAM, ADC de 12 bits, comparador, MSPM0L1306-Q1 Arm® Cortex®-M0+ de 32 Mhz para automoción con memoria flash de 64 KB, 4 KB de RAM, ADC de 12 bits, MSPM0L1343 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 8 KB, 2 KB de SRAM, ADC de 12 bits, comparador, T MSPM0L1344 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 16 KB, 2 KB de SRAM, ADC de 12 bits, comparador, MSPM0L1345 MCU Arm® Cortex®-M0+ de 32 MHz con flash de 32 KB, 4 KB de SRAM, ADC de 12 bits, comparador y TIA MSPM0L1346 MCU Arm® Cortex®-M0+ de 32 MHz de memoria flash de 64 KB, 4 KB de SRAM, ADC de 12 bits, comparador, MSPM0L2227 32MHz Arm® Cortex®-M0+ MCU with 128KB dual-bank flash, 32KB SRAM, 12-bit ADC, COMP, LCD, VBAT MSPM0L2227-Q1 MCU Arm® Cortex®-M0+ de 32 MHz con memoria flash de doble banco de 128 KB, SRAM de 32 KB, ADC, CO MSPM0L2228 MCU Arm® Cortex®-M0+ de 32 MHz c/mem. fl. de dob. ban., 256 KB, SRAM de 32 KB, ADC de 12 bits, COMP, MSPM0L2228-Q1 MCU Arm® Cortex®-M0+ de 32 MHz con memoria flash de doble banco de 256 KB, SRAM de 32 KB, ADC, CO
MCU Arm Cortex-R
AM2631 MCU Arm® Cortex®-R5F de núcleo único de hasta 400 MHz con control y seguridad en tiempo real AM2631-Q1 MCU Arm® Cortex®-R5F de núcleo único automotriz, hasta 400 MHz c/ control y seguridad en tiempo real AM2632 MCU Arm® Cortex®-R5F de doble núcleo de hasta 400 MHz con control y seguridad en tiempo real AM2632-Q1 MCU Arm® Cortex®-R5F de doble núcleo, automotriz, de hasta 400 MHz con control y seguridad en tiempo AM2634 MCU Arm® Cortex®-R5F de 4 núcleos a 400 MHz con control y seguridad en tiempo real AM2634-Q1 Unidad de microcontrolador (MCU) Arm® Cortex®-R5F de cuádruple núcleo, 400 MHz con control y segurid AM263P2 MCU Arm®Cortex®-R5F de doble núcleo de hasta 400 MHz con opTI-flash y control en tiempo real AM263P2-Q1 Microcontrolador Arm® Cortex®-R5F de 2 núcleos automotriz a 400 MHz con control en tiempo real y AM263P4 MCU Arm® Cortex®-R5F de 4 núcleos a 400 MHz con control en tiempo real y memoria expandible AM263P4-Q1 Unidad de microcontrolador (MCU) Arm® Cortex®-R5F de cuádruple núcleo, 400 MHz con encapsulado con f
Sensores de radar mmWave automotrices
AWR1243 MMIC de alto rendimiento de 76 GHz a 81 GHz para automoción AWR1443 Sensor de radar de chip único de 76 GHz a 81 GHz que integra MCU y aceler. de hardware para autom. AWR1642 Sensor de radar de chip único de 76 GHz a 81 GHz para automoción que integra una DSP y una MCU AWR1843 Sensor de radar de un solo chip de 76 GHz a 81 GHz que integra un procesador de señal digital (DSP), AWR1843AOP Sensor de radar de un solo chip de 76 GHz a 81 GHz para automoción que integra la antena en el paque AWR2243 MMIC de alto rendimiento de segunda generación de 76 GHz a 81 GHz para automoción AWR2544 Sensor de radar en chip satelital FMCW de 76-81 GHz AWR2944 SoC de alto rendimiento de segunda generación de 76 GHz a 81 GHz automotriz para radares angulares y AWR2944P Sensor de radar automotriz de un solo chip de 76 GHz a 81 GHz con RF y rendimiento de cómputo mej AWR6443 Sensor de radar de un solo chip de 60 GHz a 64 GHz para automoción que integra MCU y acelerador de r AWR6843 Sensor de radar automotriz de un solo chip de 60 GHz a 64 GHz que integra DSP, MCU y acelerador de r AWR6843AOP Sensor de radar automotriz único chip, 60GHz a 64GHz, integra la antena en el encapsulado, DSP y MCU AWRL1432 Sensor de radar automotriz mmWave de 76 GHz a 81 GHz de baja potencia y chip único AWRL6432 Sensor de radar mmWave automotriz de 57 GHz a 64 GHz de baja potencia y chip único AWRL6844 Sensor de radar mmWave de 57 GHz a 64 GHz, baja potencia, alto rendimiento y chip único para auto
Sensores de radar mmWave industriales
IWR1443 Sensor mmWave de un solo chip de 76 GHz a 81 GHz que integra MCU y acelerador de hardware IWR1642 Sensor mmWave de un solo chip de 76 GHz a 81 GHz que integra DSP y MCU IWR1843 Sensor de radar industrial de un solo chip de 76 GHz a 81 GHz que integra DSP, MCU y acelerador de r IWR1843AOP Sensor de radar industrial de un único chip de 76 GHz a 81 GHz que integra la antena en el encapsula IWR2243 MMIC de alto rendimiento industrial de 76 GHz a 81 GHz IWR2944 Radar industrial de alto rendimiento de 76 GHz a 81 GHz de chip único con procesadores digitales de IWR6243 MMIC de alto rendimiento industrial de 57 GHz a 64 GHz IWR6443 Sensor mmWave inteligente de un solo chip de 60 GHz a 64 GHz que integra MCU y acelerador de hardwar IWR6843 Sensor mmWave inteligente de un solo chip de 60 GHz a 64 GHz que integra capacidad de procesamiento IWR6843AOP Sensor inteligente de ondas milimétricas de 60 a 64 GHz de un único chip con antena integrada en el IWRL1432 Sensor de radar industrial mmWave de 76 GHz a 81 GHz de baja potencia y chip único IWRL6432 Sensor de radar industrial de ondas milimétricas de 57 GHz a 64 GHz de baja potencia y chip único IWRL6432AOP Sensor de radar mmWave industrial de 57 GHz a 63.5 GHz, baja potencia y un solo chip con antena inte IWRL6432W Sensor de radar mmWave industrial de 60 GHz y baja potencia en encapsulado de escala de oblea IWRL6844 Sensor de radar industrial mmWave de 57 GHz a 64 GHz, de alto rendimiento, baja potencia y único chi
Procesadores digitales de señales (DSP)
AM2732 MCU basada en Arm® Cortex-R5F de doble núcleo con C66x DSP, Ethernet y seguridad de hasta 400 MHz AM2732-Q1 MCU Arm® Cortex-R5F de doble núcleo para automoción de hasta 400 MHz con C66x DSP, Ethernet, segurid
Productos Wi-Fi
CC3501E SimpleLink™ wireless MCU with 2.4GHz Wi-Fi® 6 and Bluetooth® Low Energy CC3551E SimpleLink™ wireless MCU with dual-band (2.4GHz and 5GHz) Wi-Fi® 6 and Bluetooth® Low Energy
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Archivo Gerber

LAUNCHXL-F29H85X Design Files (Rev. B)

SPAC005B.ZIP (11096 KB)
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Esquema

LAUNCHXL-F29H85X Schematic (Rev. B)

SPAM003B.PDF (728 KB)
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Encapsulado Pines Símbolos CAD, huellas y modelos 3D
HTQFP (PTS) 176 Ultra Librarian
HTQFP (RFS) 144 Ultra Librarian
NFBGA (ZEX) 256 Ultra Librarian
Se aplican los Términos y condiciones estándar de TI para los elementos de evaluación.

Pedidos y calidad

Información incluida:
  • RoHS
  • REACH
  • Marcado del dispositivo
  • Acabado de plomo/material de la bola
  • Clasificación de nivel de sensibilidad a la humedad (MSL) / reflujo máximo
  • Estimaciones de tiempo medio entre fallas (MTBF)/fallas en el tiempo (FIT)
  • Contenido del material
  • Resumen de calificaciones
  • Monitoreo continuo de confiabilidad
Información incluida:
  • Lugar de fabricación
  • Lugar de ensamblaje

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