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MIPI Mobile Segment Protocol Decode Solutions Datasheet

MIPI Mobile Segment Protocol Decode Solutions Datasheet

MIPI Mobile Segment Protocol Decode Solutions Datasheet

Device driver ICs for peripherals like camera, display, memory, RF, and USB interface with application processors in mobile handsets - each of these interfaces has their own protocol to communicate to the application processor. System validation teams face constant challenges in terms of integration and validating communication between the devices. Tektronix provides a complete suite of these protocol decoders for M-PHY, D-PHY and various other interfaces in the mobile handset. The decoding solution helps designers efficiently and cost-effectively perform protocol validation in conjunction with electrical validation for MIPI specifications using a single oscilloscope.

The decoding solution offered has the ability to trigger on the signal of interest using hardware-based triggering and software-based triggering. The ability to use oscilloscope hardware triggers on live waveforms improves the accuracy of locking onto packet types of interest, search on different packet types and correlate with M-PHY electrical signals. Oscilloscope-based hardware triggering provides much higher accuracy than software triggers for capturing decoded signals. Hardware-based triggering is a unique capability offered by Tektronix for oscilloscope-based decoders. Various decoders are available and are listed below in detail.

M-PHY UniPro and LLI decode
  • Leverages the oscilloscope serial trigger (ST6G)
    • Triggers on the UniPro and LLI specific events for all Gears
  • 4-lane automated decoding
    • Automatically identifies all Gears and signaling schemes, and decodes
    • Automatically verifies CRC errors in the Protocol Packets
    • Acquires up to 4 lanes of data traffic simultaneously, and correlates the lane-to-lane events
  • Protocol to physical-layer data correlation
    • Automatically links protocol decode data to the waveforms on the oscilloscope
    • Enables faster system-level protocol debugging
M-PHY 8b-10b decode
  • All M-PHY Gears
    • Decodes M-PHY data traffic up to 6.25 Gb/s data rate, from symbols or 10-bit into 8-bit data
  • Trigger and search
    • Supports trigger and search on any control character, character/symbol, error (character error and disparity error), or pattern
  • Custom decode
    • Additionally, Option SR-CUST Custom Serial Analysis Kit can be used for any custom protocols decoding up to 6.25 Gb/s data rate
M-PHY DigRFv4 decode
  • Automated decoding
    • Automatically recognizes data speeds, disassembles, and displays the decoded data in different readable-data formats
  • 4-Lane decoding
    • Acquires up to 4 lanes of data traffic at a time
  • Online, offline, and remote analysis
    • Supports LAN interface, and leverages TekVISA to connect to Tektronix oscilloscopes
  • Filter, search, and option tabs
    • Searches and filters the decoded messages based on user criteria
SSIC Protocol Decoder
  • Leverages the oscilloscope serial trigger (ST6G)
  • Software trigger support on the SSIC specific events
  • Supports all M-PHY HS Gears & PWM Gears
  • Supports 1, 2 and 4 lanes of SSIC decoding
  • Single/Consolidated hierarchical view to display protocol decode at raw data, 8b10b, Physical Layer, Link Layer and Protocol Level
  • Generates customized reports in .mht format and PDF
RFFE Protocol Decoder
  • RFFE protocol Analysis using oscilloscope live channel data or stored RFFE signals
  • Powerful RFFE real-time protocol aware hardware based trigger capabilities
  • Displays the decoded data in RFFE frame format
  • Error checks, Search & Filter capabilities
  • Report Generation
HSI Electrical Validation & Protocol Decode
  • Automated HSI electrical measurements and protocol testing
  • Supports analysis of Synchronized data flow, Pipelined data flow and Receiver real time data flow
  • Supports Stream Transmission and Frame Transmission Modes
  • Supports wfm file formats for offline analysis

Oscilloscope-based decode for M-PHY UniPro and LLI

M-PHY design and test engineers need to monitor and debug UniPro/LLI protocol interfaces to ensure reliable operation of the system. Manually interpreting the protocol layer information using oscilloscope data is time consuming and prone to human error in a versatile UniPro and LLI protocol standard.

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PGY-UPRO and PGY-LLI Decode


 

The Prodigy PGY-UPRO/PGY-LLI Protocol Decode software offers extensive protocol decoding for M-PHY UniPro/LLI protocol specifications respectively. With this software, the M-PHY design and test engineers can now automatically make accurate and reliable decodes of multi-lane data, acquired by a Tektronix DPO/DSA/MSO70000 oscilloscope, and significantly reduce the development and test cycle.

The PGY-UPRO/PGY-LLI software automatically identifies all gears and signaling schemes such as NRZ and PWM, and decodes the protocol frames of multi-lane traffic. Built up on oscilloscope serial trigger features, the software computes CRC and verifies for CRC errors in a UniPro/LLI protocol packet. The software also links the decoded data to the electrical signal in the oscilloscope display, enabling better correlation from protocol- to physical-layer data. Furthermore, the software generates comprehensive and customizable reports, along with protocol data exportable in TXT and CSV formats. The software conforms to the M-PHY specification v1.0, the UniPro specification v1.4, and the LLI specification v0.8.

Oscilloscope-based decode for M-PHY 8b-10b

The SR-810B Serial Analysis application option enables Decode, Search, and Trigger on 8b/10b bus events for fast verification. All Tektronix MSO/DPO/DSA70000 Series oscilloscopes are equipped with a dedicated trigger chip for triggering on 8b/10b data patterns in high-speed serial signals up to 6.25 Gb/s. Installed as part of TekScope firmware, this software ensures finding even rare events. Furthermore, the DPO/DSA/MSO70000 Series oscilloscopes with PTD software support several 8b10b data values for triggering.

A very unique feature of the SR-810B option and perhaps the most powerful debugging tool is the capability to trigger on 8b/10b code errors. No serial trigger would be able to trigger on all possible character errors, disparity errors, or losses of byte synchronization, but the Tektronix 8b/10b serial trigger allows triggering on common errors such as disparity or character errors.

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Oscilloscope-based decode for M-PHY 8b-10b


 

Oscilloscope-based decode for M-PHY DigRFv4


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Oscilloscope-based decode for M-PHY DigRFv4


The Moving Pixel MPHYVIEW Protocol Decode software automatically recognizes M-PHY data speeds, disassembles, decodes the DigRFv4 data streams, and displays the decoded data in different readable-data formats. The software can be configured to acquire up to 4 lanes of data traffic at a time.

The MPHYVIEW software can be connected to a remote oscilloscope, and executed remotely from any Windows system, using TekVISA. The Filter and Search tabs enable searching and possibly highlighting records that satisfy given criteria. The MPHYVIEW also supports bit-sync, align, 10b-8b decode form packets, and disassemble.

SSIC Protocol Decoder

SSIC implementation provides low-power, efficient connectivity on a PCB between a smartphone/tablet application processor to a modem or WiFi SoC. It uses existing USB 3.0 software stack help preserve software compatibility. The electrical PHY layer MIPI M-PHY with SSIC controllers can result in up to an 80 percent power savings over USB 3.0 PHYs.

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  • Support SSIC specification v1.0 
  • Leverages the oscilloscope serial trigger (ST6G). This hardware-based triggering provides accuracy of locking on a packet type with much higher accuracy than a software trigger.
  • Software trigger support on the SSIC specific events for all M-PHY HS Gears & PWM Gears
  • Supports 1, 2 and 4 lanes of SSIC decoding
  • Single/Consolidated hierarchical view to display protocol decode at raw data, 8b10b, Physical Layer, Link Layer and Protocol Level
  • Clicking on the packets in the results tabs will center align the corresponding packet in the scope graticule providing user with ease of navigation of the decoded date
  • Search capability of different packet types, ordered set and errors
  • Protocol to physical-layer data correlation in the results tab as well as Scope graticule
  • Highlights packet errors in the results tab for easy navigation and quick analysis of errors
  • Generates customized reports in .mht format and PDF
  • Color coding of header, payload and CRC on scope graticule
  • Supports decoding for both M-PHY TX & M-PHY RX

Supported Oscilloscopes & Probes

  • Same as the recommended oscilloscopes and probes recommendation for M-PHY

Oscilloscope Options requirements

  • ST6G
  • SR-CUST

PGY-RFFE Protocol Trigger and Decode Analysis Software


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RRFE Protocol Analysis view in oscilloscope waveform display


Features:

  • RFFE protocol Analysis using oscilloscope live channel data or stored RFFE signals
  • Powerful RFFE real-time protocol aware hardware based trigger capabilities
  • Displays the decoded data in RFFE frame format
  • Error checks for parity bits of command and data
  • Error checks for Byte count with actual data count and missing SSC
  • Flexibility to view Slave ID in Symbol or Hex value
  • Flexibility to view decoded data in hex, binary, Decimal or octal format
  • Long duration data decode support to capture more number of RFFE protocol transactions
  • Search capabilities to locate protocol event
  • Filter capabilities to view information of Interest
  • Documentation by exporting data in CSV and TXT file format
  • Report Generation

RF Front End control interface (RFFE) developed for controlling front interfaces including Power Amplifiers, Low-noise amplifiers, filters, switches, and power management modules in new generation mobile devices. Engineers designing RFFE interfaces need to test and debug the RFFE interface for its protocol specification. System designers need to debug the communication taking place in the RF interface. This process is time consuming and error prone, due to manually decoding the clk and data signals of RFFE for testing and debugging the hundreds of RFFE messages.