Filter by Category
Unavailable
RGT Technology, LLC . . .
| Part Number | Manufacturer | Description | Brand | Price & Lead Time |
|---|---|---|---|---|
| VME-AIO16 | ESD | ESD VME-AIO16 CPU Board - CPU 68340, 25 MHz, 256 kbytes SRAM, 16 A/D channels (16 Bit), UIN = ±10 V, 4 D/A channels (16 Bit)Max. sample rate 45 kHz (only one channel used) Simple Type: CPU Board VME-AIO16 is an intelligent VMEbus board, containing 6 or 16 analog differential inputs and is ideally suited for fast and flexible data acquisition. It includes all necessary components on a VMEbus 6U board and needs one slot. The AIO16 contains a local MC 68340 CPU at 25 MHz for the execution of complex data acquisition algorithms. The CPU section of the AIO16 contains 256 kbytes of SRAM, EPROM and two RS-232 interfaces. Configuration parameters may be stored in an EEPROM. AIO16 contains 256 kbytes of shared SRAM, as well, to form the interface between local CPU and VMEbus. Designed for use of A/D converters with 16 bits resolution, the AIO16 can also be equipped with 12 bits resolution converters. The input voltage range with standard components is ±10 V. By varying the resistance values, other voltage ranges as well as current measurement (±20 mA) are possible. The A/D converters synchronize via an external trigger signal or via software. The included software allows you to obtain the following sampling rates: the maximum sampling rate from trigger signal to reception of the A/D-data in the SRAM is 33 kHz when sampling all 16 channels synchronously. If sampling only 8 channels synchronously, the maximum sampling rate is 40 kHz, for just one channel it is 45 kHz. In addition to the analog inputs, the AIO16 board contains 4 bipolar ±10 V D/A converter outputs with a resolution of 16 bits. These D/A converters allow internal calibration and offset adjustment of the input amplifiers. Connect each D/A converter to one of four A/D inputs via a multiplexer for this result. Of course, the user can also use these D/A converter outputs directly as process outputs. Download the datasheet (PDF) | Request Quote | |
| VME-AIO16-12 | ESD | ESD VME-AIO16-12 CPU Board - CPU 68340, 25 MHz, 256 kbytes SRAM, 16 A/D channels (16 Bit), UIN = ±10 V, 4 D/A channels (12 Bit), High data throughput by means of local intelligence Simple Type: CPU Board VME-AIO16 is an intelligent VMEbus board, containing 6 or 16 analog differential inputs and is ideally suited for fast and flexible data acquisition. It includes all necessary components on a VMEbus 6U board and needs one slot. The AIO16 contains a local MC 68340 CPU at 25 MHz for the execution of complex data acquisition algorithms. The CPU section of the AIO16 contains 256 kbytes of SRAM, EPROM and two RS-232 interfaces. Configuration parameters may be stored in an EEPROM. AIO16 contains 256 kbytes of shared SRAM, as well, to form the interface between local CPU and VMEbus. Designed for use of A/D converters with 16 bits resolution, the AIO16 can also be equipped with 12 bits resolution converters. The input voltage range with standard components is ±10 V. By varying the resistance values, other voltage ranges as well as current measurement (±20 mA) are possible. The A/D converters synchronize via an external trigger signal or via software. The included software allows you to obtain the following sampling rates: the maximum sampling rate from trigger signal to reception of the A/D-data in the SRAM is 33 kHz when sampling all 16 channels synchronously. If sampling only 8 channels synchronously, the maximum sampling rate is 40 kHz, for just one channel it is 45 kHz. In addition to the analog inputs, the AIO16 board contains 4 bipolar ±10 V D/A converter outputs with a resolution of 16 bits. These D/A converters allow internal calibration and offset adjustment of the input amplifiers. Connect each D/A converter to one of four A/D inputs via a multiplexer for this result. Of course, the user can also use these D/A converter outputs directly as process outputs. Download the datasheet (PDF) | Request Quote | |
| VME-AIO16-126 | ESD | ESD VME-AIO16-12/6 CPU Board - CPU 68340, 25 MHz, 256 kbytes SRAM, 6 A/D channels (12 Bit), UIN = ±10 V, 4 D/A channels (16 Bit), High data throughput by means of local intelligence Simple Type: CPU Board VME-AIO16 is an intelligent VMEbus board, containing 6 or 16 analog differential inputs and is ideally suited for fast and flexible data acquisition. It includes all necessary components on a VMEbus 6U board and needs one slot. The AIO16 contains a local MC 68340 CPU at 25 MHz for the execution of complex data acquisition algorithms. The CPU section of the AIO16 contains 256 kbytes of SRAM, EPROM and two RS-232 interfaces. Configuration parameters may be stored in an EEPROM. AIO16 contains 256 kbytes of shared SRAM, as well, to form the interface between local CPU and VMEbus. Designed for use of A/D converters with 16 bits resolution, the AIO16 can also be equipped with 12 bits resolution converters. The input voltage range with standard components is ±10 V. By varying the resistance values, other voltage ranges as well as current measurement (±20 mA) are possible. The A/D converters synchronize via an external trigger signal or via software. The included software allows you to obtain the following sampling rates: the maximum sampling rate from trigger signal to reception of the A/D-data in the SRAM is 33 kHz when sampling all 16 channels synchronously. If sampling only 8 channels synchronously, the maximum sampling rate is 40 kHz, for just one channel it is 45 kHz. In addition to the analog inputs, the AIO16 board contains 4 bipolar ±10 V D/A converter outputs with a resolution of 16 bits. These D/A converters allow internal calibration and offset adjustment of the input amplifiers. Connect each D/A converter to one of four A/D inputs via a multiplexer for this result. Of course, the user can also use these D/A converter outputs directly as process outputs. Download the datasheet (PDF) | Request Quote | |
| VME-AIO16-6 | ESD | ESD VME-AIO16-6 CPU Board - CPU 68340, 25 MHz, 256 kbytes SRAM, 6 A/D channels (16 Bit), UIN = ±10 V, 4 D/A channels (16 Bit), Easy operation by shared RAM interface Simple Type: CPU Board VME-AIO16 is an intelligent VMEbus board, containing 6 or 16 analog differential inputs and is ideally suited for fast and flexible data acquisition. It includes all necessary components on a VMEbus 6U board and needs one slot. The AIO16 contains a local MC 68340 CPU at 25 MHz for the execution of complex data acquisition algorithms. The CPU section of the AIO16 contains 256 kbytes of SRAM, EPROM and two RS-232 interfaces. Configuration parameters may be stored in an EEPROM. AIO16 contains 256 kbytes of shared SRAM, as well, to form the interface between local CPU and VMEbus. Designed for use of A/D converters with 16 bits resolution, the AIO16 can also be equipped with 12 bits resolution converters. The input voltage range with standard components is ±10 V. By varying the resistance values, other voltage ranges as well as current measurement (±20 mA) are possible. The A/D converters synchronize via an external trigger signal or via software. The included software allows you to obtain the following sampling rates: the maximum sampling rate from trigger signal to reception of the A/D-data in the SRAM is 33 kHz when sampling all 16 channels synchronously. If sampling only 8 channels synchronously, the maximum sampling rate is 40 kHz, for just one channel it is 45 kHz. In addition to the analog inputs, the AIO16 board contains 4 bipolar ±10 V D/A converter outputs with a resolution of 16 bits. These D/A converters allow internal calibration and offset adjustment of the input amplifiers. Connect each D/A converter to one of four A/D inputs via a multiplexer for this result. Of course, the user can also use these D/A converter outputs directly as process outputs. Download the datasheet (PDF) | Request Quote | |
| VME-CAN4 | ESD | ESD VME-CAN4 I/O Controller - Intelligent CAN interface board with 4 independent CAN channels 11 and 29 bits CAN identifier (SJA 1000), integrated firmware with CAL/CMS and CANopen support Simple Type: I/O Controller The VME-CAN4 includes on a VMEbus 6U board 4 complete, independent CAN interfaces to the VMEbus and needs one slot. Each interface is equipped with its own micro controller of type 68331 at 20 MHz clock frequency. Each micro controller has a working memory of 256 kbytes available. After a RESET, the micro controller program code is loaded from the local Flash EPROM. Program updates can be loaded into the Flash EPROM via the VMEbus. The CAN data transfer from and to the VMEbus is performed via a Shared RAM with a capacity of 512 kbytes and FIFOs. Received Rx data generates a local interrupt processed by the belonging micro controller. It stores the data in the Shared RAM and the identifier is stored in the FIFO (FIFO to master).Then it generates a VMEbus interrupt. An individual interrupt vector generates for each of the four CAN channels. To transmit CAN data, the VMEbus master enters the data into the Shared RAM. With this, automatically a pointer to the identifier is stored in the FIFO (FIFO to slave). The belonging micro controller reads FIFO and RAM and starts the data transmission. The included CAN controller of type SJA1000 supports the standard CAN protocol (11 bits identifier) as well as the extended CAN protocol (29 bits identifier). The physical CAN layer is according to ISO 11898 for a maximum baud rate of up to 1 Mbit/s. The baud rate programming can range between 10 kbits/s and 1 Mbit/s via the VMEbus. The CAN channels are electrically isolated from each other as well as from the VME section. Four DC/DC converters perform the local supply of the four channels. With electrical isolation as a standard, esd guarantees a transfer rate of 1 Mbit/s for a bus length of 37 m, if the other CAN participants are equipped with equivalent CAN interfaces. 9-pole DSUB female connectors at the front panel perform connection of the CAN nets. For other layers or connector standards, a piggyback interface is available. Download the datasheet (PDF) | Request Quote | |
| VME-CAN4-1 | ESD | ESD VME-CAN4-1 I/O Controller - Intelligent CAN interface board with 1 independent CAN channels 11 and 29 bits CAN identifier (SJA 1000), integrated firmware with CAL/CMS and CANopen support Simple Type: I/O Controller The VME-CAN4 includes on a VMEbus 6U board 4 complete, independent CAN interfaces to the VMEbus and needs one slot. Each interface is equipped with its own micro controller of type 68331 at 20 MHz clock frequency. Each micro controller has a working memory of 256 kbytes available. After a RESET, the micro controller program code is loaded from the local Flash EPROM. Program updates can be loaded into the Flash EPROM via the VMEbus. The CAN data transfer from and to the VMEbus is performed via a Shared RAM with a capacity of 512 kbytes and FIFOs. Received Rx data generates a local interrupt processed by the belonging micro controller. It stores the data in the Shared RAM and the identifier is stored in the FIFO (FIFO to master).Then it generates a VMEbus interrupt. An individual interrupt vector generates for each of the four CAN channels. To transmit CAN data, the VMEbus master enters the data into the Shared RAM. With this, automatically a pointer to the identifier is stored in the FIFO (FIFO to slave). The belonging micro controller reads FIFO and RAM and starts the data transmission. The included CAN controller of type SJA1000 supports the standard CAN protocol (11 bits identifier) as well as the extended CAN protocol (29 bits identifier). The physical CAN layer is according to ISO 11898 for a maximum baud rate of up to 1 Mbit/s. The baud rate programming can range between 10 kbits/s and 1 Mbit/s via the VMEbus. The CAN channels are electrically isolated from each other as well as from the VME section. Four DC/DC converters perform the local supply of the four channels. With electrical isolation as a standard, esd guarantees a transfer rate of 1 Mbit/s for a bus length of 37 m, if the other CAN participants are equipped with equivalent CAN interfaces. 9-pole DSUB female connectors at the front panel perform connection of the CAN nets. For other layers or connector standards, a piggyback interface is available. Download the datasheet (PDF) | Request Quote | |
| VME-CAN4-2 | ESD | ESD VME-CAN4-2 I/O Controller - Intelligent CAN interface board with 2 independent CAN channels 11 and 29 bits CAN identifier (SJA 1000), integrated firmware with CAL/CMS and CANopen support Simple Type: I/O Controller The VME-CAN4 includes on a VMEbus 6U board 4 complete, independent CAN interfaces to the VMEbus and needs one slot. Each interface is equipped with its own micro controller of type 68331 at 20 MHz clock frequency. Each micro controller has a working memory of 256 kbytes available. After a RESET, the micro controller program code is loaded from the local Flash EPROM. Program updates can be loaded into the Flash EPROM via the VMEbus. The CAN data transfer from and to the VMEbus is performed via a Shared RAM with a capacity of 512 kbytes and FIFOs. Received Rx data generates a local interrupt processed by the belonging micro controller. It stores the data in the Shared RAM and the identifier is stored in the FIFO (FIFO to master).Then it generates a VMEbus interrupt. An individual interrupt vector generates for each of the four CAN channels. To transmit CAN data, the VMEbus master enters the data into the Shared RAM. With this, automatically a pointer to the identifier is stored in the FIFO (FIFO to slave). The belonging micro controller reads FIFO and RAM and starts the data transmission. The included CAN controller of type SJA1000 supports the standard CAN protocol (11 bits identifier) as well as the extended CAN protocol (29 bits identifier). The physical CAN layer is according to ISO 11898 for a maximum baud rate of up to 1 Mbit/s. The baud rate programming can range between 10 kbits/s and 1 Mbit/s via the VMEbus. The CAN channels are electrically isolated from each other as well as from the VME section. Four DC/DC converters perform the local supply of the four channels. With electrical isolation as a standard, esd guarantees a transfer rate of 1 Mbit/s for a bus length of 37 m, if the other CAN participants are equipped with equivalent CAN interfaces. 9-pole DSUB female connectors at the front panel perform connection of the CAN nets. For other layers or connector standards, a piggyback interface is available. Download the datasheet (PDF) | Request Quote | |
| VME-CAN4-64 | ESD | ESD VME-CAN4-64 I/O Controller - CAN layer according to ISO 11898 with 9-pole DSUBs or DeviceNet interface, SDS Smart Distributed System Simple Type: I/O Controller The VME-CAN4 includes on a VMEbus 6U board 4 complete, independent CAN interfaces to the VMEbus and needs one slot. Each interface is equipped with its own micro controller of type 68331 at 20 MHz clock frequency. Each micro controller has a working memory of 256 kbytes available. After a RESET, the micro controller program code is loaded from the local Flash EPROM. Program updates can be loaded into the Flash EPROM via the VMEbus. The CAN data transfer from and to the VMEbus is performed via a Shared RAM with a capacity of 512 kbytes and FIFOs. Received Rx data generates a local interrupt processed by the belonging micro controller. It stores the data in the Shared RAM and the identifier is stored in the FIFO (FIFO to master).Then it generates a VMEbus interrupt. An individual interrupt vector generates for each of the four CAN channels. To transmit CAN data, the VMEbus master enters the data into the Shared RAM. With this, automatically a pointer to the identifier is stored in the FIFO (FIFO to slave). The belonging micro controller reads FIFO and RAM and starts the data transmission. The included CAN controller of type SJA1000 supports the standard CAN protocol (11 bits identifier) as well as the extended CAN protocol (29 bits identifier). The physical CAN layer is according to ISO 11898 for a maximum baud rate of up to 1 Mbit/s. The baud rate programming can range between 10 kbits/s and 1 Mbit/s via the VMEbus. The CAN channels are electrically isolated from each other as well as from the VME section. Four DC/DC converters perform the local supply of the four channels. With electrical isolation as a standard, esd guarantees a transfer rate of 1 Mbit/s for a bus length of 37 m, if the other CAN participants are equipped with equivalent CAN interfaces. 9-pole DSUB female connectors at the front panel perform connection of the CAN nets. For other layers or connector standards, a piggyback interface is available. Download the datasheet (PDF) | Request Quote | |
| VME-DAC1612-x | ESD | ESD VME-DAC1612-x I/O Controller - x channels unipolar/bipolar 0...+10 V, -10...+10 V, (x = 04, 08, 16), Multiple output voltage ranges possible, optionally current outputs for 8 channels Simple Type: I/O Controller The VME-DAC1612 is an interface board designed for the generation of up to 16 analog signals for process control purposes. Select output voltages 0...+5 V, 0...+10 V, ±5 V or ±10 V. Set the corresponding jumper on the board to make your selection. Use the potentiometers to adjust gain and offset. The VME-DAC1612 includes adjustments for bipolar voltages Conversion of the output voltage (0...+10 V) into an output current (0...20 mA or 4...20 mA) is possible with option VME-DAC812-20mA for 4 or 8 channels. Fast magnetic coupling barriers IL715 and DC/DC-converters perform the electrical isolation between VMEbus and analog process section. The P2 connector links both the external power supply inputs of the analog section and the process signals to the system. esd electronics, Inc. recommends the option DAC1612-ADAPT1 or DAC1612-ADAPT2 for connecting the signals from P2 with ribbon cable to an industrial mounted module (according to DIN EN 50022) with terminal blocks. Two 34-pin post connectors on the front panel allow easy accessibility to the analog outputs. Download the datasheet (PDF) | Request Quote | |
| VME-DPIO32 | ESD | ESD VME-DPIO32 I/O Controller - 32 digital I/Os, PWM, counter, timer, All 32 outputs programmable for pulse width modulation (PWM) or gating control Simple Type: I/O Controller VME-DPIO32 contains 32 opto-isolated digital process I/O channels. It includes all necessary components on a VMEbus 6U board and needs one slot. The 32 digital I/O channels are programmable in 8 groups of 4 channels as inputs or outputs. The 8 groups are electrically isolated from each other. The input channels accept an input voltage range of 5 VDC to 30 VDC. Each input channel can generate an interrupt on the VMEbus and that is programmable to rising or to falling edge. The inputs are overvoltage protected between -3 VDC and +35 VDC. The digital output channels accept an operating voltage range of 6 VDC to 24 VDC with a rated current of 0.3 A. The output drivers are the components LMD18400. The protection circuit of the driver is activated by short-circuit, over temperature and overvoltage. The drivers generate an error signal in the following conditions: no load, short-circuit to GND, to VCC , overvoltage or over temperature of the driver module. In addition to the bit programmable operating mode of the outputs, it is possible to use the single output channels via the pulse processor components HD63143 for pulse-width modulation (PWM). A total of 2 x 24 programmable 16-bit registers for switching period and resolution are available. The minimum pulse width amounts to 10 :s. You can synchronize the outputs. Download the datasheet (PDF) | Request Quote | |
| VME-DVI | ESD | ESD VME-DVI I/O Controller with IBM PPC 405GP, 200 MHz 32 MB SDRAM, 32 MB Flash, graphics controller Simple Type: CPU Board The powerful graphics controller 69030 offers display modes from 640x480 (true color) at 85 Hz up to 1600x1200 (16 bit colors) at 60 Hz. The DVI-I-interface controls CRT-monitors by analog video signals as well as TFT-monitors by digital video signals. The VME-DVI comes with an ETHERNET interface for 10 Mbit/s and 100 Mbit/s nets. It is accessible as 10/100BaseT via RJ45 connector in the front panel. The board provides 2 CAN interfaces based on SJA1000 CAN controllers. The board routes TTL-level CAN signals to the VME P2 connector. Both CAN allow data transfer rates of 1 Mbit/s. One of two RS-232 serial ports is available via a DSUB9 connector in the front panel, the other one via the VMEbus P2 connector. The flash memory carries a standard ppcboot and enables the VME-DVI to boot various operating systems from network and onboard Flash. The VME-DVI directly supports Linux and VxWorks with full support of onboard drivers by esd, others on request. There is also a bunch of higher layer protocols like CANopen, DeviceNet as well as an on-board web server available. Graphics drivers are available for VxWorks, RTOS/UH, Linux and QNX. The module supports Windows 98/NT/2000, and other drivers are available on request. Download the datasheet (PDF) | Request Quote | |
| VME-ISER12 | ESD | ESD VME-ISER12 CPU Board - Intelligent interface board, with 12 serial channels on-board, 10 RS-232 interfaces, Functions and connections compatible to VME-ISER8 Simple Type: CPU Board The VME-ISER12 is an intelligent VMEbus interface w/ 12 serial process interfaces, and an additional RS-232 interface for connecting a terminal for service & programming. The serial controller SAB 82538 controls 8 serial interfaces, and the CPU 68360 controls 4 as well as the terminal interface via the SCC. Opto-couplers and DC/DC converters electrically isolate the interfaces & VMEbus potentials. Piggybacks locally realize the physical interfaces RS-232, RS-422, RS-485, & TTY-passive. The standard option has RS-232 drivers in sockets connecting via the VMEbus connector P2. The board is double Europe format with 4 TE (1 slot) width. The VMEbus connector P2 has 9 serial channels available. If needed, an additional channel connects via a front panel 9-pin post connector. A second DSUB-connector in the front panel is for the terminal interface (RS-232). The TTL-signals of the serial channels connect to two 50-pin post connectors. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY | ESD | ESD VME-PMC-CADDY I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to PMC-Update from 22.10.96 (no interconnection between PMC-modules) Simple Type: I/O Controller The VMEbus unit PMC-CADDY is a VME64 base unit that can carry up to two PMC modules of normal size or one module of double size. For the VMEbus connection, the VME-PCI Bridge UNIVERSE CA91C142 by Tundra With an internal clock rate of 33 MHz is used. The CA91C142 interface can operate either as either slave or as Master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. The PMC-CADDY operates with a data width of up to 32 bits and with 32 address signals on the VMEbus. You can apply the VMEbus interrupt to any of the seven interrupt-request lines. The board connects to the VMEbus by two 160-pin VG-connectors according to IEC603-xx on VME64 extensions. A red LED shows an active VMEbus-interrupt request in the front panel and a yellow LED shows a VMEbus access onto the board. Draft standard IEEE P1386/Draft 2.0 is the standard used for both PMC plug-in units' design except for the standard I/O pin routing. This design makes it possible to insert any PMC modules on the market. In addition to the connectors for the PMC address/ data and control signals, every plug-in unit of the PMC-CADDY has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules (acc. to PMC-Update of FORCE ™, Table 1, Author: Wayne Fischer, Director of Strategic Programs CMC/PMC Working Groups Chair, 22.10.96). In the option -32P, the pin assignment is acc. to IEEE P1386/Draft 2.0, Table 6-3. This pin assignment offers to connect the two PMC-modules via P2, because several PMC-I/O-signals short at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY2 | ESD | ESD VME-PMC-CADDY/2 I/O Controller - VMEbus CPU board for two single PMC modules, P2-pin assignment acc. to Vita 35 (P4V2-64ac, P4V0-64) (no interconnection between PMC-modules), no XMC, 3.3 V supply for PMC fed from VMEbus Simple Type: I/O Controller The VMEbus unit VME-PMC-CADDY/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, esd electronics uses the VME-PCI Bridge Tsi148 by Tundrap. The Tsi148 design allows the board to operate either as slave or as master on the VMEbus. Operating as a master, it supports a 4-level arbiter. The VMEbus interrupt can be applied to any of the seven interrupt-request lines. Two 160-pin VG-connectors (complementary to DIN41612) connect the board to the VMEbus for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. The two PMC slots, designed according to the standard IEEE Std 1386-2001 (except the standard I/O pin routing)), make it possible to insert all PMC modules using 3.3 V signaling. In addition to the connectors for the PMC address/data and control signals, every slot of the VME-PMC-CADDY/2 has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’ the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY2-32P2 | ESD | ESD VME-PMC-CADDY/2-32P2 I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to IEEE Std P1386-2001, Table 8 (interconnection between 16 pins of the PMC-modules), no XMC, 3.3 V supply for PMC fed from VMEbus Simple Type: I/O Controller The VMEbus unit VME-PMC-CADDY/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, esd electronics uses the VME-PCI Bridge Tsi148 by Tundrap. The Tsi148 design allows the board to operate either as slave or as master on the VMEbus. Operating as a master, it supports a 4-level arbiter. The VMEbus interrupt can be applied to any of the seven interrupt-request lines. Two 160-pin VG-connectors (complementary to DIN41612) connect the board to the VMEbus for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. The two PMC slots, designed according to the standard IEEE Std 1386-2001 (except the standard I/O pin routing)), make it possible to insert all PMC modules using 3.3 V signaling. In addition to the connectors for the PMC address/data and control signals, every slot of the VME-PMC-CADDY/2 has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’ the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY2-CC | ESD | ESD VME-PMC-CADDY/2-CC I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to IEEE Std P1386-2001, Table 8 (interconnection between 16 pins of the PMC-modules), no XMC, 3.3 V supply for PMC fed from VMEbus, extended temperature range Simple Type: I/O Controller The VMEbus unit VME-PMC-CADDY/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, esd electronics uses the VME-PCI Bridge Tsi148 by Tundrap. The Tsi148 design allows the board to operate either as slave or as master on the VMEbus. Operating as a master, it supports a 4-level arbiter. The VMEbus interrupt can be applied to any of the seven interrupt-request lines. Two 160-pin VG-connectors (complementary to DIN41612) connect the board to the VMEbus for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. The two PMC slots, designed according to the standard IEEE Std 1386-2001 (except the standard I/O pin routing)), make it possible to insert all PMC modules using 3.3 V signaling. In addition to the connectors for the PMC address/data and control signals, every slot of the VME-PMC-CADDY/2 has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’ the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY2-T | ESD | ESD VME-PMC-CADDY/2-T I/O Controller - VMEbus CPU board for two single PMC modules, P2-pin assignment acc. to Vita 35 (P4V2-64ac, P4V0-64) (no interconnection between PMC-modules), no XMC, 3.3 V supply for PMC fed from VMEbus, extended temperature range Simple Type: I/O Controller The VMEbus unit VME-PMC-CADDY/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, esd electronics uses the VME-PCI Bridge Tsi148 by Tundrap. The Tsi148 design allows the board to operate either as slave or as master on the VMEbus. Operating as a master, it supports a 4-level arbiter. The VMEbus interrupt can be applied to any of the seven interrupt-request lines. Two 160-pin VG-connectors (complementary to DIN41612) connect the board to the VMEbus for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. The two PMC slots, designed according to the standard IEEE Std 1386-2001 (except the standard I/O pin routing)), make it possible to insert all PMC modules using 3.3 V signaling. In addition to the connectors for the PMC address/data and control signals, every slot of the VME-PMC-CADDY/2 has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’ the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY-32P2 | ESD | ESD VME-PMC-CADDY-32P2 I/O Controller - VMEbus base board for two 32P2 single PMC modules, P2-pin assignment acc. to IEEE P1386/ Draft 2.0, Table 6-3 (interconnection between 16 pins of the PMC-modules), extended temperature range on request Simple Type: I/O Controller The VMEbus unit PMC-CADDY is a VME64 base unit that can carry up to two PMC modules of normal size or one module of double size. For the VMEbus connection, the VME-PCI Bridge UNIVERSE CA91C142 by Tundra With an internal clock rate of 33 MHz is used. The CA91C142 interface can operate either as either slave or as Master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. The PMC-CADDY operates with a data width of up to 32 bits and with 32 address signals on the VMEbus. You can apply the VMEbus interrupt to any of the seven interrupt-request lines. The board connects to the VMEbus by two 160-pin VG-connectors according to IEC603-xx on VME64 extensions. A red LED shows an active VMEbus-interrupt request in the front panel and a yellow LED shows a VMEbus access onto the board. Draft standard IEEE P1386/Draft 2.0 is the standard used for both PMC plug-in units' design except for the standard I/O pin routing. This design makes it possible to insert any PMC modules on the market. In addition to the connectors for the PMC address/ data and control signals, every plug-in unit of the PMC-CADDY has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules (acc. to PMC-Update of FORCE ™, Table 1, Author: Wayne Fischer, Director of Strategic Programs CMC/PMC Working Groups Chair, 22.10.96). In the option -32P, the pin assignment is acc. to IEEE P1386/Draft 2.0, Table 6-3. This pin assignment offers to connect the two PMC-modules via P2, because several PMC-I/O-signals short at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY-3.3P1 | ESD | ESD VME-PMC-CADDY-3.3P1 I/O Controller - 3.3V power supply directly connected to VMEbus 3.3V, not generated from 5V supply, extended temperature range on request Simple Type: I/O Controller The VMEbus unit PMC-CADDY is a VME64 base unit that can carry up to two PMC modules of normal size or one module of double size. For the VMEbus connection, the VME-PCI Bridge UNIVERSE CA91C142 by Tundra With an internal clock rate of 33 MHz is used. The CA91C142 interface can operate either as either slave or as Master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. The PMC-CADDY operates with a data width of up to 32 bits and with 32 address signals on the VMEbus. You can apply the VMEbus interrupt to any of the seven interrupt-request lines. The board connects to the VMEbus by two 160-pin VG-connectors according to IEC603-xx on VME64 extensions. A red LED shows an active VMEbus-interrupt request in the front panel and a yellow LED shows a VMEbus access onto the board. Draft standard IEEE P1386/Draft 2.0 is the standard used for both PMC plug-in units' design except for the standard I/O pin routing. This design makes it possible to insert any PMC modules on the market. In addition to the connectors for the PMC address/ data and control signals, every plug-in unit of the PMC-CADDY has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules (acc. to PMC-Update of FORCE ™, Table 1, Author: Wayne Fischer, Director of Strategic Programs CMC/PMC Working Groups Chair, 22.10.96). In the option -32P, the pin assignment is acc. to IEEE P1386/Draft 2.0, Table 6-3. This pin assignment offers to connect the two PMC-modules via P2, because several PMC-I/O-signals short at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CADDY-T | ESD | ESD VME-PMC-CADDY-T I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to PMC-Update from 22.10.96 (no interconnection between PMC-modules) extended temperature range: -40...+75 Simple Type: I/O Controller The VMEbus unit PMC-CADDY is a VME64 base unit that can carry up to two PMC modules of normal size or one module of double size. For the VMEbus connection, the VME-PCI Bridge UNIVERSE CA91C142 by Tundra With an internal clock rate of 33 MHz is used. The CA91C142 interface can operate either as either slave or as Master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. The PMC-CADDY operates with a data width of up to 32 bits and with 32 address signals on the VMEbus. You can apply the VMEbus interrupt to any of the seven interrupt-request lines. The board connects to the VMEbus by two 160-pin VG-connectors according to IEC603-xx on VME64 extensions. A red LED shows an active VMEbus-interrupt request in the front panel and a yellow LED shows a VMEbus access onto the board. Draft standard IEEE P1386/Draft 2.0 is the standard used for both PMC plug-in units' design except for the standard I/O pin routing. This design makes it possible to insert any PMC modules on the market. In addition to the connectors for the PMC address/ data and control signals, every plug-in unit of the PMC-CADDY has an I/O-connector that applies the I/O signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O-pin of the PMC modules (acc. to PMC-Update of FORCE ™, Table 1, Author: Wayne Fischer, Director of Strategic Programs CMC/PMC Working Groups Chair, 22.10.96). In the option -32P, the pin assignment is acc. to IEEE P1386/Draft 2.0, Table 6-3. This pin assignment offers to connect the two PMC-modules via P2, because several PMC-I/O-signals short at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CPU2 | ESD | ESD VME-PMC-CPU/2 I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to VITA 35 (P4V2-64ac, P4V0-64), (no interconnection between PMC modules) Simple Type: I/O Controller The Tsi148 allows the board to operate either as slave or as master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. Any of the seven-interrupt request lines accepts application of the VMEbus interrupt, and the board connects to the VMEbus by two 160-pin VG-connectors (complementary to DIN41612) for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. A high efficient PowerPC MPC8349 powers the board at 533 or 667 MHz with the advantage of frugal power consumption. The fast floating-point unit of type 603 allows complex algorithms at formidable speed. The memory enables ECC with a capacity of 512 Mbyte or optional 1 Gbyte DDR2-typed RAM. The flash memory of 2 Gbyte allows even complex and ambitious operating systems as well as user's application. The on-board FPGA controls the set-up of the board resources, including the complex Tsi148 VME interface and the PMC slots, but is mighty enough to enable a programming API for the programmers usage. The board also includes 2 Gbit Ethernet ports, 2 USB 2.0 Hi-Speed ports and 2 RS-232 serial ports with access through the front panel. Various LEDs signal state of operation - also usable at programmers demand. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CPU2-32P | ESD | ESD VME-PMC-CPU/2-32P I/O Controller - VMEbus base board for two 32P2 single PMC modules, P2-pin assignment acc. to IEEE Std 1386-2001, Table 8 (interconnection between 16 pins of the PMC-modules) Simple Type: I/O Controller The Tsi148 allows the board to operate either as slave or as master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. Any of the seven-interrupt request lines accepts application of the VMEbus interrupt, and the board connects to the VMEbus by two 160-pin VG-connectors (complementary to DIN41612) for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. A high efficient PowerPC MPC8349 powers the board at 533 or 667 MHz with the advantage of frugal power consumption. The fast floating-point unit of type 603 allows complex algorithms at formidable speed. The memory enables ECC with a capacity of 512 Mbyte or optional 1 Gbyte DDR2-typed RAM. The flash memory of 2 Gbyte allows even complex and ambitious operating systems as well as user's application. The on-board FPGA controls the set-up of the board resources, including the complex Tsi148 VME interface and the PMC slots, but is mighty enough to enable a programming API for the programmers usage. The board also includes 2 Gbit Ethernet ports, 2 USB 2.0 Hi-Speed ports and 2 RS-232 serial ports with access through the front panel. Various LEDs signal state of operation - also usable at programmers demand. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CPU2-CC | ESD | ESD VME-PMC-CPU/2-CC I/O Controller - VMEbus base board for two single PMC modules, P2-pin assignment acc. to VITA 35 (P4V2-64ac, P4V0-64), (no interconnection between PMC modules). Conduction Cooled, extended temperature range: -40...+85ºC. Simple Type: I/O Controller The VMEbus unit VME-PMC-CPU/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, the VME-PCI bridge Tsi148 by Tundra is used. The Tsi148 allows the board to operate either as slave or as master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. Any of the seven-interrupt request lines accepts application of the VMEbus interrupt, and the board connects to the VMEbus by two 160-pin VG-connectors (complementary to DIN41612) for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. A high efficient PowerPC MPC8349 powers the board at 533 or 667 MHz with the advantage of frugal power consumption. The fast floating-point unit of type 603 allows complex algorithms at formidable speed. The memory enables ECC with a capacity of 512 Mbyte or optional 1 Gbyte DDR2-typed RAM. The flash memory of 2 Gbyte allows even complex and ambitious operating systems as well as user's application. The on-board FPGA controls the set-up of the board resources, including the complex Tsi148 VME interface and the PMC slots, but is mighty enough to enable a programming API for the programmers usage. The board also includes 1 Gbit Ethernet port and 2 RS-232 serial ports with access through PO rear I/O pins. Designed according to the IEEE STD 1386-2001 standard (except the standard I/O pin routing), both PMC slots allow insertion of all PMC modules, that use 3.3 V signaling only. In addition to the connectors for the PMC address/ data and control signals, every slot of the VME-PMC-CPU/2-CC has an I/O connector that applies the I/O-signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O pin of the PMC-modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’, the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2, because several PMC-I/O-signals are shorted at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CPU2-CC-32P2 | ESD | ESD VME-PMC-CPU/2-CC-32P2 I/O Controller - VMEbus base board for two 32P2 single PMC modules, P2-pin assignment acc. to IEEE Std 1386-2001, Table 8 (interconnection between 16 pins of the PMC-modules). Conduction Cooled, extended temperature range: -40...+85ºC. Simple Type: I/O Controller The VMEbus unit VME-PMC-CPU/2 is a VME64-base board that can carry up to two PMC modules of normal size. For the VMEbus connection, the VME-PCI bridge Tsi148 by Tundra is used. The Tsi148 allows the board to operate either as slave or as master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. Any of the seven-interrupt request lines accepts application of the VMEbus interrupt, and the board connects to the VMEbus by two 160-pin VG-connectors (complementary to DIN41612) for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. A high efficient PowerPC MPC8349 powers the board at 533 or 667 MHz with the advantage of frugal power consumption. The fast floating-point unit of type 603 allows complex algorithms at formidable speed. The memory enables ECC with a capacity of 512 Mbyte or optional 1 Gbyte DDR2-typed RAM. The flash memory of 2 Gbyte allows even complex and ambitious operating systems as well as user's application. The on-board FPGA controls the set-up of the board resources, including the complex Tsi148 VME interface and the PMC slots, but is mighty enough to enable a programming API for the programmers usage. The board also includes 1 Gbit Ethernet port and 2 RS-232 serial ports with access through PO rear I/O pins. Designed according to the IEEE STD 1386-2001 standard (except the standard I/O pin routing), both PMC slots allow insertion of all PMC modules, that use 3.3 V signaling only. In addition to the connectors for the PMC address/ data and control signals, every slot of the VME-PMC-CPU/2-CC has an I/O connector that applies the I/O-signals of the PMC modules to VMEbus connector P2. Two different P2 pin assignments are available: In the standard configuration, each P2-pin connects to one I/O pin of the PMC-modules acc. to VITA 35 (P4V2-64ac, P4V0-64). In the option ‘-32P’, the pin assignment is acc. to IEEE Std 1386-2001, Table 8. This pin assignment offers the connection of the two PMC-modules via P2, because several PMC-I/O-signals are shorted at P2. Download the datasheet (PDF) | Request Quote | |
| VME-PMC-CPU2-T | ESD | ESD VME-PMC-CPU/2-T I/O Controller - Master or slave functionality, 2eVME and 2eSST fast protocol, Slots according to IEEE Std 1386-2001 specified Simple Type: I/O Controller The Tsi148 allows the board to operate either as slave or as master on the VMEbus. If the board operates as master, it supports a 4-level arbiter. Any of the seven-interrupt request lines accepts application of the VMEbus interrupt, and the board connects to the VMEbus by two 160-pin VG-connectors (complementary to DIN41612) for VME64 systems. LEDs in the front panel indicate an active VMEbus-interrupt request and a VMEbus access onto the board. A high efficient PowerPC MPC8349 powers the board at 533 or 667 MHz with the advantage of frugal power consumption. The fast floating-point unit of type 603 allows complex algorithms at formidable speed. The memory enables ECC with a capacity of 512 Mbyte or optional 1 Gbyte DDR2-typed RAM. The flash memory of 2 Gbyte allows even complex and ambitious operating systems as well as user's application. The on-board FPGA controls the set-up of the board resources, including the complex Tsi148 VME interface and the PMC slots, but is mighty enough to enable a programming API for the programmers usage. The board also includes 2 Gbit Ethernet ports, 2 USB 2.0 Hi-Speed ports and 2 RS-232 serial ports with access through the front panel. Various LEDs signal state of operation - also usable at programmers demand. Download the datasheet (PDF) | Request Quote |