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White Rabbit is a fully deterministic Ethernet-based network for general purpose data transfer and synchronization. It can synchronize over 1000 nodes with sub-ns accuracy over fiber lengths of up to 10 km. Commercially available. More info at the Wiki page
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The VFC is a VME carrier for two VITA 57 (FMC) mezzanines. For more details please refer to the wiki pages. Obsolete project. Replaced by VFC-HD.
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FmcAdc100M14b4cha is a 4 channel 100MSPS 14 bit ADC low pin count FPGA Mezzanine Card (VITA 57). More info at the Wiki page
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A fine delay generator in FMC format with 1 input and 4 outputs. The resolution is 1 ns. Commercially available. More info at the Wiki page
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A simple 4-lane PCIe carrier for a low pin count FPGA Mezzanine Card (VITA 57). It supports the White Rabbit timing and control network. Commercially available. Linux and Labview drivers available for some mezzanine cards. More info at the Wiki page
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Etherbone is an FPGA-core that connects Ethernet to internal on-chip wishbone buses permitting any core to talk to any other across Ethernet.
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Development of software for the White Rabbit switch, and in particular the embedded Linux system running in the ARM9 processor. More info at the Wiki page
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An FPGA Mezzanine Card (FMC) with a Time to Digital Converter chip to perform one-shot sub-nanosecond time interval measurements. Commercially available. More info at the Wiki page
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PHASE (Portable Hardware Analyzer with Sharing Explorer) aims at unifying hardware debugging in a single tool. From the host machine, a user may graphically interconnect components to describe the connection between his computer and the target device to debug. For example, a USB JTAG cable might be the root node, connected to an Arria2 development board with a CPLD and an FPGA, containing a LM32 processor.
Wherever possible, PHASE fetches design descriptions from the internet based on the detected JTAG IDCODEs, USB vendor IDs, or PnP BUS information. In the preceding example, each step of the chain would be automatically detected. The USB cable from the vendor+product codes, the FPGA from the JTAG IDCODE and the LM32 from the Arria2's sld hub. The user would now be presented with read/write access to the data and instruction buses for visual inspection or firmware loading. Furthermore, the user could launch gdb to halt and single-step the embedded LM32 CPU.
If a device is not yet described, the user may assemble a driver out of the reusable software components. For example, an Altera USB-Blaster driver is just a FTDI device chained with a byte packeter and a JTAG bit banger. Once the design has been graphically assembled, it is automatically scanned for attached JTAG devices and the USB cable design is shared online with any future users of the same cable.
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A collection of platform-independent cores such as memories, synchronizer circuits and Wishbone cores.
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This project defines data structures, to be embedded in the FPGA memory address space, to enumerate the devices that have been synthetized in the current design. The same structure is also used as a simple flash file system. AKA Self-Describing Bus (SDB) Specification for Logic Cores. The layout is simple enough to be parsed both by the host and by the internal soft-core, if any.
The documentation is public, and related code is GNU GPL licensed.
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FmcDIO5chTTLa is a 5-bit port digital IO card in FMC form-factor. Each single-bit port can be configured individually as input or output. The I/Os on LEMO 00 connectors are TTL compatible. Commercially available. More info at the Wiki page
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A simple VME64x carrier for two low pin count FPGA Mezzanine Cards (VITA 57). It has memory and clocking resources and supports the White Rabbit timing and control network. Commercially available. More info at the Wiki page
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Software support for the SPEC board, including kernel and user-space Linux code. The package also include the fmc-bus driver, which is expected to be used by other carriers as well.
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A software framework for Linux device drivers aimed at supporting controls and data acquisition hardware. ZIO supports sub-nanosecond timestamps, block-oriented input and output and transport of meta-data with the data samples. Users can change the buffer type and trigger type associated with a device at run time, and all of devices, triggers and buffers are easily implemented as add-on modules.
The PF_ZIO implementation, currently in beta status, implements a network interface to the ZIO transport, which allows each I/O channel to generate or receive network frames. Applications see the network of devices and can talk with several of them from the same socket. We support SOCK_STREAM, SOCK_DGRAM and SOCK_RAW.
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We have designed an FPGA Mezzanine card (standard FMC/Vita 57) for high-channel-count electrophysiology, with 128 channels (potentially up to 512), based upon Intan Tech's RHA2132 (2 uV rms input-referred noise), sampled at 25kHz 18bit by AD7982. We are basing our design on the reference design provided by Reid Harrison of Intan Tech for their 16-channel evaluation board. The expected cost of the device should be under 5000$.
In order to have an integrated solution we intend to have as default carrier the Opal Kelly Shuttle LX1, an inexpensive USB FMC carrier with an excellent USB controller. The integrated solution will be completed with software on the PC side to grab to disk continuously and/or display in some fashion all 128 channels.
Our status: We have an alpha card. It has passed most tests---we can grab from any channel at 1MS/s. We have an alpha microcode: it grabs from any channel and stores on the PC.
Our current team: Marcelo Magnasco (Rockefeller University, New York), design. Andres Cicuttin (ICTP, Trieste), schematics + fpga Maria Liz Crespo (ICTP, Trieste), fpga Sanjee Abeytunge (MSKCC, New York) layout Nicholas Joseph (RU) Macintosh drivers
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The robustness of a White Rabbit Network (WRN) is a broad subject covering methods (HW & SW) which enable to increase overall reliability of a WR-based system. This includes Forward Error Correction (FEC), Quality of Service (QoS) assurance, support of network redundancy, proper network design, thorough diagnostics, and increasing the reliability of network components (i.e. switches, nodes). Here, these methods are described and their implementation sources gathered.
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A project to host all software and hardware developments related to testing the White Rabbit switch.
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