ac6-training, un département d'Ac6 SAS
 
Site displayed in English (USA)
Site affiché en English (USA)View the site in FrenchVoir le site en English (GB)
go-up

ac6 >> ac6-training >> Processors >> NXP Power CPUs >> MPC55XX implementation Inquire Download as PDF Write us

FM2 MPC55XX implementation

This course covers MPC5554 and MPC5567 NXP MCUs

formateur
Objectives
  • The course explains how to design a MPC5554 board.
  • The e200 core is studied in detail, especially the MMU, the cache and the SPE instruction set.
  • The course explains how to develop a generic interrupt handler.
  • The training highlights data paths between core and peripherals through the internal crossbar switch.
  • The host programming of eTPU and eMIOS is viewed in details.

  • This course has been delivered several times to companies developing automotive and avionics systems.
A lot of programming examples have been developed by ACSYS to explain the boot sequence and the operation of complex peripherals, such as eQADC and eMIOS.
•  They have been developed with Diab Data compiler and are executed under Lauterbach debugger.
A more detailed course description is available on request at training@ac6-training.com
  • Theoretical course
    • PDF course material (in English) supplemented by a printed version for face-to-face courses.
    • Online courses are dispensed using the Teams video-conferencing system.
    • The trainer answers trainees' questions during the training and provide technical and pedagogical assistance.
  • At the start of each session the trainer will interact with the trainees to ensure the course fits their expectations and correct if needed
  • Any embedded systems engineer or technician with the above prerequisites.
  • The prerequisites indicated above are assessed before the training by the technical supervision of the traineein his company, or by the trainee himself in the exceptional case of an individual trainee.
  • Trainee progress is assessed by quizzes offered at the end of various sections to verify that the trainees have assimilated the points presented
  • At the end of the training, each trainee receives a certificate attesting that they have successfully completed the course.
    • In the event of a problem, discovered during the course, due to a lack of prerequisites by the trainee a different or additional training is offered to them, generally to reinforce their prerequisites,in agreement with their company manager if applicable.

Course Outline

  • Internal architecture of the MPC55XX
  • Functional pin multiplexing
  • Memory map, internal register space
  • Connection of peripherals to the core platform
  • Differences between the new Book E architecture and the classic PowerPC architecture
  • The instruction pipeline
  • Integer and floating point execution units
  • SPE instruction set, signal processing capability, new data types
  • Vector and scalar floating point
  • The MMU, 32-entry fully associative TLB, page size selection
  • Hardware assist for TLB miss exception
  • Page attributes WIMGE
  • Process protection, variable number of PID registers and sharing
  • TLB initialization
  • The 32-kB unified L1 cache, pseudo round-robin replacement algorithm, 8-way set associativity
  • 8-entry store buffer
  • Cache-related instructions
  • ABI : sections
  • Book E exception handling
  • Core timers
  • Nexus emulation
  • Watchpoint logic
  • Up to 504 on-chip module interrupt sources
  • Software vs hardware vector mode
  • Hardware acceleration for ISRs : use of 9-bit vectors
  • Preemption, priority management
  • External IRQs
  • FMPLL
  • Configuration pins
  • Reset configuration halfword
  • Boot assist module, 4 different boot modes
  • MMU configuration after BAM executes
  • Initialization sequence
  • External bus interface, pinout
  • Memory controller with support for SDR flash and SRAM
  • Compatibility with the external bus of the MPC5XX
  • Support for external master accesses to internal addresses
  • Burst support
  • Chip-select programming
  • 2 MB on-chip flash
  • Integrated ECC
  • Censorship protection
  • Read while write operation
  • Erase and program sequences
  • 111 kB on-chip SRAM : general purpose SRAM, cache and eTPU RAMs
  • Autonomous IO control
  • Parallel memory bus architecture, concurrent accesses
  • Programmable master priorities on a per-slave basis
  • 64 independent channels with link capability
  • Parking on slave ports
  • Transfer control descriptors, inner and outer loops, modulo feature
  • Scatter / gather feature
  • DMA channel arbitration
  • DMA error reporting
  • Real time hardware events processing, scheduling, priority scheme
  • Microengine operation
  • New arithmetic, logical and control instructions
  • Angle clock hardware
  • DMA support
  • Dual eTPU shared resources
  • Introduction to the eTPU functions QOM, NITC, PWM, SIOP, UART
  • Channel service max latency time calculation
  • eTPU development tools, Ashware debugger
  • Introduction to time functions supported by the 24 unified channels
  • DMA request per channel
  • Pin serialization / deserialization
  • eMIOS interrupt requests
  • Double action submodules
  • PWM submodules, center aligned PWM
  • Windowed programmable time accumulation
  • Quadrature decode
  • Analog inputs multiplexing
  • 12-bit AD resolution
  • Queue management, trigger sources
  • Conversion queue priority scheme
  • Conversion cycle times
  • eQADC command / data flow
  • Hardware interface
  • ADC error correction
  • SPI protocol explanation, master / slave operation
  • Command queue
  • Flexible programming transfer attributes on a per-frame basis
  • Transmit and receive sequences
  • UART basics
  • Double buffering
  • Wake up mode
  • Transmit and receive sequences
  • Support for LIN master operation
  • CAN protocol basics
  • Message buffer structure
  • Mask registers
  • Listen-only mode capability
  • Receive and Transmit processes
  • Error counters
  • Overview
  • MII pinout
  • Buffer descriptor description
  • Initialization sequence
  • Error management
  • Interrupts
  • FLEXRAY protocol basics
  • FLEXRAY controller characteristic
  • Message buffer structure
  • Clock synchronisation mechanism
  • Initialization
  • Error management
  • Interrupts