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ORSO82G5-1F680I
- Part Number: ORSO82G5-1F680I
- Categories:
- Manufacturer: Lattice Semiconductor Corporation
- MOQ: 1PCS
- In Stock: N/A
- Datasheet:
- Description: IC FPGA 372 I/O 680FBGA
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Specifications
ORSO82G5-1F680I details
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Datasheets
ORSO82G5-1F680I Specifications
| Manufacturer | Lattice Semiconductor Corporation |
| Mounting Type | Surface Mount |
| Number of I/O | 372 |
| Package / Case | 680-BBGA |
| Product Status | Obsolete |
| Total RAM Bits | 113664 |
| Number of Gates | 643000 |
| Voltage - Supply | 1.425V ~ 3.6V |
| Number of LABs/CLBs | - |
| Operating Temperature | -40°C ~ 85°C (TA) |
| Supplier Device Package | 680-FPBGA (35x35) |
| Number of Logic Elements/Cells | 10368 |
ORSO82G5-1F680I FPGAs Overview
The ORSO42G5 and ORSO82G5-1F680I support a clockless high-speed interface for interdevice communication on a board or across a backplane. The built-in clock recovery of the ORSO42G5 and ORSO82G5-1F680I allows higher system performance, easier-to-design clock domains in a multiboard system and fewer signals on the backplane. Network designers will benefifit from using the backplane transceiver as a network termination device. Sister devices, the ORT42G5 and the ORT82G5, support 8b/10b encoding/decoding and link state machines for 10 Gbit Ethernet (XAUI) and Fibre Channel. The ORSO42G5 and ORSO82G5-1F680I perform SONET data scrambling/descrambling, streamlined SONET framing, limited Transport OverHead (TOH) handling, plus the programmable logic to terminate the network into proprietary systems. The cell processing feature in the ORSO42G5 and ORSO82G5-1F680I makes them ideal for interfacing devices with any proprietary data format across a high-speed backplane. For non-SONET applications, all SONET functionality is hidden from the user and no prior networking knowledge is required. The ORSO42G5 and ORSO82G5-1F680I are completely pin-compatible with the ORT42G5 and ORT82G5 devices.
The Lattice Programmable Logic ICs series ORSO82G5-1F680I is FPGA - Field Programmable Gate Array ORCA FPSC 2.7Gbits/s BP XCVR 643K, View Substitutes & Alternatives along with datasheets, stock, pricing from Authorized Distributors at bitfoic.com,
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Features
• High-speed SERDES programmable serial data rates of 0.6 Gbps to 2.7 Gbps.
• Asynchronous operation per receive channel (separate PLL per channel).
• Transmit pre-emphasis (programmable) for improved receive data eye opening.
• Provides a 10 Gbps backplane interface to switch fabric using four work and, with the ORSO82G5, four protect 2.5 Gbit/s links. Also supports port cards at rates between 0.6 Gbps and 2.7 Gbps.
• Allows wide range of applications for SONET network termination, as well as generic data moving for high-speed backplane data transfer.
• No knowledge of SONET/SDH needed in generic applications. Simply supply data (75 MHz-168.75 MHz clock) and at least a single frame pulse.
• High-Speed Interface (HSI) function for clock/data recovery serial backplane data transfer without external clocks.
• Four- or eight-channel HSI functions provide 2.7 Gbps serial user data interface per channel for a total chip bandwidth of >10Gbps or >20 Gbps (full duplex).
• SERDES has low-power CML buffers and support for 1.5V/1.8V I/Os.
• SERDES HSI automatically recovers from loss-of-clock once its reference clock returns to normal operating state.
• Powerdown option of SERDES HSI receiver and/or transmitter on a per-channel basis.
• Ability to mix half-rate and full-rate between the channels with the same reference clock.
• Ability to confifigure each SERDES block independently with its own reference clock.
• STS-48 framing in SONET mode.
• Programmable enable of SONET scrambler/descrambler, A1/A2 insertion and B1 generation and checking.
• Insertion and checking of link assignment values to facilitate interconnection and debugging of backplanes.
• Optional AIS-L insertion during loss-of-frame.
• Optional RDI-L insertion to indicate remote far-end defects for maintenance capabilities.
• SPE signal marks payload bytes in SONET mode.
• Frame alignment across multiple ORSO42G5 and ORSO82G5 devices for work/protect switching at STS-
768/STM-256 and above rates.
• Supports transparent mode where Transport OverHead (TOH) bytes are user-generated in the FPGA.
• Supports two modes of in-band management and confifiguration with TOH byte extraction/insertion by the Embedded core. A1/A2 and B1 insertion can be independently enabled.
– AUTO_SOH where the embedded core inserts the A1/A2 framing bytes, performs the B1 calculation and inserts the B1 byte. All other bytes are passed through unchanged from the FPGA logic as in transparent mode.
– AUTO_TOH where all of the overhead bytes are set by the embedded core. Most of the bytes are set to zero. At the receive side, all of the TOH bytes except those set to a non-zero value can be ignored.
• Optional A1/A2 corruption, B1 byte corruption, and K2 byte corruption for system debug purposes.
• Built-in boundary scan (IEEE 1149.1 and 1149.2 JTAG), including the SERDES interface.
• FIFOs align incoming data across all eight channels (ORSO82G5 only), groups of four channels, or groups of two channels. Optional ability to bypass alignment FIFOs for asynchronous operation between channels is also provided. (Each channel includes its own recovered clock and frame pulse)
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ORSO82G5-1F680I Packaging
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Its sensitive components are not in contact with the measured object, also known as a non-contact temperature measuring instrument. This instrument can be used to measure the surface temperature of moving objects, small targets, and objects with small heat capacity or rapid temperature changes (transient), and can also be used to measure the temperature distribution of the temperature field. The most commonly used non-contact thermometers are based on the fundamental law of black body radiation and are called radiation thermometers. Radiation thermometry methods include the brightness method (see optical pyrometer), radiation method (see radiation pyrometer), and colorimetric method (see colorimetric thermometer). All kinds of radiation temperature measurement methods can only measure the corresponding photometric temperature, radiation temperature, or colorimetric temperature. 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There are two types of changes in resistance positive temperature coefficient Increased temperature = increased resistance A decrease in temperature = a decrease in resistance negative temperature coefficient Increased temperature = decreased resistance Decrease in temperature = increase in resistance Thermocouple Sensing A thermocouple consists of two metal wires of different materials welded together at the ends. Then measure the ambient temperature of the non-heating part, and the temperature of the heating point can be accurately known. Since it must have two conductors of different materials, it is called a thermocouple. Thermocouples made of different materials are used in different temperature ranges, and their sensitivities also vary. The sensitivity of the thermocouple refers to the change in the output potential difference when the temperature of the heating point changes by 1 °C. For most thermocouples supported by metallic materials, this value is between 5 and 40 microvolts/°C. Since the sensitivity of the thermocouple temperature sensor has nothing to do with the thickness of the material, it can also be made into a temperature sensor with very thin materials. Also due to the good ductility of the metal material used to make thermocouples, this tiny temperature-measuring element has a very high response speed and can measure rapidly changing processes. Selection method If you want to make reliable temperature measurements, you first need to choose the correct temperature instrument, that is, the temperature sensor. Among them, thermocouples, thermistors, platinum resistance thermometers (RTDs), and temperature ICs are the most commonly used temperature sensors in testing. The following is an introduction to the characteristics of the thermocouple and thermistor temperature instruments. thermocouple Thermocouples are the most commonly used temperature sensors in temperature measurement. Its main advantages are a wide temperature range and adaptability to various atmospheric environments, and it is strong, low in price, does not require a power supply, and is the cheapest. A thermocouple consists of two wires of dissimilar metals (metal A and metal B) connected at one end. When one end of the thermocouple is heated, there is a potential difference in the thermocouple circuit. The temperature can be calculated from the measured potential difference. However, there is a nonlinear relationship between voltage and temperature. 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