DPhyDecoderV1.2 Datasheet and Users Manual v1.0
Contents
1. Overall Dimensions 345mm x 195mm x 80mm Approximate without supply Note that this product is RoHS compliant even though it is currently exempt from RoHS requirements For more information contact The Moving Pixel Company 4905 SW Griffith Drive Suite 106 Beaverton Oregon 97005 www movingpixel com information movingpixel com 1 503 626 9663 phone PST2. 036 inch 0 050 inch For usage information see section 4 below 3 5 SMA inputs In Rx mode signal acquisition from the DUT is via 10 SMA connectors two for the differential clock lane and two for each differential lane for up to 4 data lanes Lanes are labeled at the Decoder end of the cable In Rx mode these signals are actively terminated by the unit in response to the protocol on the wires 4 Operation 4 1 Modes There are two modes of operation Sniff mode and Rx mode Sniff mode acquires the signal from the DUT via the active solder down probe heads This is generally used mid bus when there is a DPhy Transmitter connected to a DPhy receiver and the user wants to monitor and or decode the traffic on the bus The active probes non invasively allow the user to monitor the traffic The unit does not interact with either the transmitter or the receiver 4 2 Connections 4 2 1 Sniff mode Connect the USB cable to the PC and the probe heads to the DUT Make sure the black ground wire is attached to the DUT ground We have found that the best way to connect the solder down probes to the DUT is to solder short 7mm whisker wires to each of the probe tips then down to the DUT Tie the probe head to the DUT with some electrical tape to stabilize the setup and strail relieve the whisker wires If short whisker wires cannot work for a particular setup the user can extend the length
3. be unplugged and removed from inside the unit Removal will keep the probe head out of the user s way and lessen the likelihood of damage but remember where you put it they are easy to lose and quite expensive to replace Probe polarity is identified in the following illustration Probe should connect to D PHY lane Dp with probe connecting to D PHY Dn If the input resistors to the probe become damaged as a result of soldering de soldering etc they may be replaced with 1 33 K 1 0603 resistors All normal soldering and ESD precautions must be observed Probe head tip resistors are user replaceable 10 spare resistors are provided for each probe head Users are cautioned that probe tip resistor soldering replacement requires a fair bit of skill in order to avoid damage to the probe head circuit board CCDNEE KBR se x ae HEZSEBHINK ee a N When soldering the probe directly to traces or pads or vias care must be taken to prevent mechanical stress to the probe head else circuit damage may result The colors on the end of the probes are meaningless They are provided to help with probe logistics When shipped Data Lane one is Red Data Lane two is Green Clock is Clear Data Lane three is Blue and Data Lane 4 is White following the resistor color code The probes are all interchangeable including the clock However calibration will be slightly affected by interchanging the probes 1 05 inch
4. margin such that it does not actually need to train to recover the signal as long as it was transmitted within spec since the timing variation allowed in the spec is less than the acquisition setup and hold time required by the DPhyDkd However if the transmitter is out of spec the signal can still be acquired by using the methods outlined in the paragraph above 4 3 5 0 Electrical specification for the DPhyDkd Characteristic Specification Notes Maximum data rate 2 5 Gb s per lane Maximum clock rate 1250 MHz Input Impedance active probes 2 0k to ground in This will slightly reduce the parallel with less than pF each side of the Differential input LP voltage high signal depending on the output impedance of the source Trigger Out impedance 50 ohms Trigger Out amplitude 3 3V open circuit 1 65V into 50 ohms Logic low is ground Probe Head tip resistors 1 33k 1 0603 package style lead free Storage Capacity video data 256MBytes 512Mbytes total vector storage half is overhead Clock delay range 9 nS External Power Supply 24 Vdc 50 watts max Universal supplied Operating Environment 20 30 degrees C Less than 15 000 elevation No condensing humidity Lab environment No strong stray fields No static discharges Weight 1170 grams approximate without supply Weight power supply and cord 475 grams approximate
5. From left to right they are and indicate as follows Idle Green There is no traffic at the present time HSTraffic Green There is High Speed traffic present LP Traffic Green There is Low Power traffic present BTA Green A Bus Turn Around cycle is in progress ULPS Green Bus is in Ultra Low Power State TriggerGreen The trigger conditions specified via the GUI have been met Errors Red not sticky the associated indicator in the GUI is sticky CRC and or Checksum errors have been detected The reason this indicator is not sticky is so that a user can get a real time feel for the error rate and feedback if the user is making an adjustment that may affect the error rate Spare Yellow this is reserved for future use Currently it comes on at power up and stays on 3 4 Probe heads In Sniff mode signal acquisition from the DUT is via 5 active solder down probe heads one for the clock lane and one each for up to 4 data lanes Lanes are labeled at the Decoder end of the cable For the highest electrical performance we recommend a small whisker of wire be soldered between the probe tip end and the circuit under test This will give the system some mechanical flexibility and will help prevent damage to either the probe tip ends or the circuit under test Unused probe heads should be wrapped up in an antistatic container such as a nickel bag If a user expects to not use particular lanes long term the probe head and cable can
6. aaa DPhy v1 2 Decoder MIPI 2 5Gb s Protocol Decoder Hardware DataSheet amp User Manual June 2015 Rev 1 0 MIPI DPhy Decoder 1 0 General The MIPI DPhy v1 2 Decoder DPhyDkd is the hardware probe that supports MIPI DPhy signal acquisition with protocol decode occuring on a host Windows PC Users familiar with the predecessor product DphyDecoder will note a nearly complete overlap of function and look and feel The DPhyDkd supports e sophisticated real time triggering Rx mode and Sniff mode real time status monitoring activity statistics status LED indicators Sniff mode active probes solder down for minimal loading of the device under test Rx mode includes internal active termination and SMA connectors e USB 3 0 for fast data transfer The control and decode software that is provided with DPhyDkd DPhyDecoderCtl interfaces to the hardware and provides the following features e Configuration control e Disassembly of the captured information in a logic analyzer like format e Reassembly and display of any video information captured e Storage of captured video frame s to a file s Refer to the DPhyDecoderCtl document for a detailed treatment of all the software features DPhyDkd support up to 4 data lanes and 1 clock lane Data rate operation up to 2 5 Gb s per lane is supported Connection to the DUT is via 5 active solder down probes supplied one per lane or via SMA for Rx mode P
7. e unit Upon power up the left most two leds Idle and HS Traffic will blink back and forth a few times to indicate that the internal boot process is complete This system is intended to be operated in a lab environment where proper grounding of all equipment and surfaces is implemented The system monitors very small signals across a very wide frequency range and is easily upset by large EM fields and static discharges 4 3 Clock delay line setting The DPhyDkd was designed to operate with systems that may not be within spec particularly with respect to the clock to data timing relationship We have provided an adjustment available through the GUI so that a user can optimize the timing As the user operates closer to the maximum clock rate limit for the DPhyDkd the setting becomes more sensitive with number of lanes this setting gets very critical working over a 400pS range typically at 1 5Gbps A clue that the timing needs adjustment is that the DPhyDkd has no errors at lower frequencies If it detects errors at the highest bit rates the user should try changing this setting over a 200pS range The GUI has a button that automates the search for the best possible setting of this delay line 4 4 Synchronization In MIPI DPhy v1 2 at bitrates greater than 1 5 Gbps transmitters are required to send a training sequence periodically so that receivers can optimize their sampling phase The DPhyDkd hardware has enough timing
8. ower for the DPhyDkd comes from an external desktop universal power supply It also features a Trigger output on an SMA connector that can drive into a 50 ohm termination Configuration and control and PC acquisition of the captured data from the DPhyDkd is via a USB 3 0 connection to the PC based software application DPhyDecoderCtl Refer to the DPhyDecoderCtl manual for the details of operating this software 2 0 Requirements e The DPhyDkd must be connected to a PC via USB 2 0 USB3 0 e The PC must be running the DphyDecoderCtl application and must have the drivers provided installed correctly This will require Admin privelages on the PC e The PC must be running Microsoft Windows Win7 32 64 bit or Win 8 e The MIPI DPhy signals being monitored must be nearly within specification from both a protocol and an electrical point of view This becomes more important as the link bitrate increases 3 Connections and Indicators 3 1 USB The USB connection between the unit and the PC is made via the rear panel The connector is labeled USB It accepts the B end of a mini USB 3 0 cable The cable provided has enhanced retention features 3 2 Power This is covered in the next section Usage 3 3 Front Panel Indicator LEDs There are 8 front panel indicators Except as noted they are sticky in that if an event occurs the LED will light for a fixed period of time so that a human observer can see it happen
9. to the probe head by soldering a 100 200 ohm resistor to the DUT then extending the other end to the probe head This wire can be up to 40mm before significant signal degradation occurs Note that this additional resistance will cause some degradation of the DPhy signal amplitude In critical applications the probe tip resistors value should be reduced by the amount of the additional external resistance 4 2 2 Rx Mode Connect the DUT transmitter to the SMA connections via high quality 50 ohm coaxial cables We recommend the length not exceed 70cm The limitation is not due to the high speed nature of the signal it is due to MIPI DPhy LP mode not being terminated at the receiver and yet having fairly fast risetimes Longer connections result in many reflections during LP signals After about 90cm of length the decoder may get confused by the reflections In Rx mode the unit actively terminates the signals as required by the protocol Further it will also respond as programmed by the user via the DphyDecoderCtl GUI to BTA requests as a normal receiver would This response is rudimentary and the unit does not have the capability to respond differently to different types of BTA requests Connect the external 24 volt power supply to DPhyDkd via the connector on the rear panel marked 24 Vdc Note that there is a LED visible through a hole next to the power connector This LED will light with a green color when power is applied to th
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