Phytec

CANmodul-592

The CANmodul-592 is an extension of the miniMODUL-535 that is based on the Philips PCB80C592 single-chip microcontroller. The 80C592 is pin and instruction set compatible to the 80C535 and other 8051-family derivatives. However, it offers such supplemental integrated features as an I2C bus, 24 parallel, bi-directional I/Os; an 8-channel ADC with 10-bit resolution; two PWM-outputs with 8-bit resolution and a Watchdog Timer. The controller is augmented by 32 KB external SRAM and 128 KB external Flash. User code is directly downloaded into the Flash via RS-232 with help of the included PHYTEC FlashTools firmware. The module communicates by means of an RS-232 transceiver, operates within a standard temperature range of 0 to 70º C and requires a low 5 V./ 100 mA. power source.

kitCON-515

All boards in the PHYTEC kitCON series are in EURO-card dimensions (160 x 100 mm.) and offer a 60 x 90 mm. wrap field for easy integration of user-designed peripheral hardware/circuitry. All peripheral hardware needed for immediate power-up is on-board, including DB-9 nodes (configurable as RS-232 and/or RS-485/CAN) and power connectors. This hardware set-up makes the kitCON series a perfect evaluation board, as well as an insert-ready engine to drive user hardware developments. The kitCON-5xx supports the C515C microcontroller from Infineon.

microMODUL-8051

The microMODUL-8051 attains its matchbox-size via the advanced SMD- and multilayer technology and can accommodate a variety of PLCC-44 or QFP-44 packaged 80C32/8051 compatible controllers. A complex logic chip allows the microMODUL to be populated by most 8051-compatible controllers in a 44-pin PLCC or QFP package. The standard memory configuration of the board features 32 (up to 128) KB SRAM and 128 (up to 512) KB Flash for storage of user code. The Flash device enables on-board programming with the included PHYTEC FlashTools firmware. All applicable controller and logic signals extend to standard-width (2.54 mm.) pin header rows located on three edges of the board, allowing it to be plugged as a "big chip" into target applications and standard bread/carrier boards. Free Chip-Select signals enable connectivity to external peripherals. The module communicates by means of an RS-232 transceiver (optionally configurable as RS-485). It operates within a standard industrial temperature range of 0 to 70° C and requires a low 5 V./ 150 mA. power source.

microMODUL-8051/LP

The microMODUL-8051/Low Power combines PHYTEC's matchbox-sized 8051 compatible microMODUL with minimum power requirements. With its 11-channel, 12-bit A/D-converter and various low power modes, the board is particularly well-suited for data acquisition and processing over longer time horizons. The low power microMODUL-8051 is populated with the Dallas DS80C323. It offers energy-saving functions such a Sleep-Mode, in which the Vcc power supply is suspended and such important on-board components as RAM, RTC and wake-logic are supplied via a battery buffer. In Power-Down mode only the controller is suspended. Idle-Mode provides the smallest power savings yet offers a very quick latent reaction time. The standard memory configuration of the board features 32 (up to 512) KB SRAM and 256 (up to 512 or as low as 32) KB Flash for storage of user code. Free Chip-Select signals enable connectivity to external peripherals. The module communicates by means of an RS-232 transceiver.

miniMODUL-167

The miniMODUL-167 is intended for use in memory-intensive applications and in driving a CAN-bus interface. The size of a credit card (85 by 55 mm.), the standard board is populated with the Infineon C167CR controller and runs at a 20 MHz clock speed, delivering instruction cycles in 100 ns. The standard memory configuration boasts 256 KB (up to 2 MB) SRAM and Flash on-board for DATA and CODE storage. PHYTEC FlashTools enable easy on-board download of user code. The board also features a Real-Time Clock which, like the SRAM, can be buffered by an external battery. All controller signals and ports extend to 2.54 mm. pitch pin headers aligning three edges of the board. These pins provide a 16-bit bi-directional I/O port and 64+ free port lines, and a 16-channel ADC with 10-bit resolution. The module is mounted with an RS-232 transceiver supporting two serial interfaces and a CAN transceiver. The miniMODUL-167 has a standard temperature range from 0 to 70 degrees C. (optional extended range from -40 to 85 degrees C.) and requires a low 250 mA. power source.

miniMODUL-515C

The miniMODUL-515/CAN is PHYTEC's first 8-bit miniMODUL to support Full 2.0B CAN. The C515C was developed using ACMOS technology, rendering the controller highly useful in applications where power consumption and dissipation are critical. The board offers 32 (to 160) KB SRAM and 128 (to 512) KB Flash enabling direct on-board programming with help of the included PHYTEC FlashTools firmware. Flexible memory mapping is enabled by software. All controller signals - including an 8-channel A/D-converter with 8/10-bit resolution, three programmable Timers/Counters and the CAN interface - extend to standard-width (2.54 mm.) header pin rows aligning three edges of the board. The board communicates by means of an RS-232 transceiver, operates within a standard industrial temperature range of 0... 70° C. and requires a low +5V./ 100 mA. power source.

miniMODUL-552

The miniMODUL-552 is an extension of the miniMODUL-535 but is based on the Philips PCB80C552 single-chip microcontroller. The 80C552 is pin and instruction set compatible to the 80C535 and other 8051-family derivatives. However, it offers such supplemental integrated features as an I²C bus, 24 parallel, bi-directional I/Os; an 8-channel ADC with 10-bit resolution; two PWM-outputs with 8-bit resolution and a Watchdog Timer. The controller is augmented by 32 KB external SRAM and 128 KB external Flash. User code is directly downloaded into the Flash via RS-232 with help of the included PHYTEC FlashTools firmware. The module communicates by means of an RS-232 transceiver, operates within a standard temperature range of 0 to 70º C and requires a low 5 V./ 100 mA. power source. It can be programmed with the included 8051-compatible C compiler, assembler and debugger evaluation software.

nanoMODUL-164

Based on the newest developments in SMD and multi-layer technology, the nanoMODUL-164 brings Infineon 16-bit power and CAN connectivity to a very minimal form factor (47 x 38 mm.). Slightly smaller than the microMODUL, the nanoMODUL represents a continuation of PHYTEC's line of miniature Single Board Computers. Based on the Infineon C164CI controller, the board delivers instruction cycles in 100 ns., enabling speedy data throughput. The on-chip 8-channel A/D-converter with 10-bit resolution, Full 2.0B CAN interface and all other controller signals extend to standard-width (1.27 mm.) pin rows (120 pin headers) aligning the board's edges. The pin header rows enable the board to be plugged like a "big chip" into target applications. The standard memory configuration boasts 256 KB (to 1 MB, yet limited to 512 KB if the CAN interface is active) of both SRAM and Flash memory. The module communicates by means of an RS-232 serial interface, which also supports convenient on-board programming of the Flash device, memory mapping and remote software updating. The module requires a single 5 V. power source and operates within a standard temperature range of 0° … +70° C.

phyCORE-167

The phyCORE-167/ST10F168 supports high-end 16-bit controllers from Infineon featuring on-chip CAN and Flash. The module is intended for use in memory-intensive applications and in driving a CAN-bus interface. Smaller than a credit card (55 by 47 mm.), the standard board is populated with the Infineon C167CR controller, runs at a 20 MHz clock speed and offers a standard external memory of 256 KB (to 1 MB) SRAM and 256 KB (to 2 MB) Flash. PHYTEC FlashTools enable easy on-board download of user code. All controller signals and ports extend to 2x100-pin rows of high-density (0.635) Molex connectors aligning two edges of the board. These pins provide a 16-bit bi-directional I/O port, 64+ free port lines, a 16-channel ADC with 10-bit resolution and two RS-232 interfaces. If populated with the C167CS, 2 Full 2.0B CAN interfaces are available via two P82C251 CAN transceivers. The C167CR and ST10F168 support a single CAN interface. A special feature of the board is the ability to reroute the controller CAN signals from the address lines, enabling direct external addressing of up to 16 MB address space.

phyCORE-167 HS/E

The phyCORE-167 HS/E (High-Speed Ethernet) supports various 144-pin devices in MQFP package from Infineon. The board offers up to 1 MB external SRAM, 2 MB external Flash and supports on-board in-system (ISP) Flash programming. If populated with the C167CS (optionally C167CR), the module offers dual on-chip 2.0B CAN. The C167Cx provides 111 I/O-lines and a supplemental UART for a second serial (modem-capable) interface. The Cirrus Logic C58900A controller enables Ethernet communication with a transmission rate of 10 Mbit/s. The minimal form factor and enhanced EMI characteristics of the phyCORE render the module an excellent subassembly to drive OEM applications.

phyCORE-591

The phyCORE-591 is populated with Philips P8xC591 controller which features CAN 2.0B on-chip via Philips PeliCAN, which offers both 11-bit and 29-bit message identifier support, an extended receipt buffer of up to 64 bytes and integrated protocol support for CANopen, DeviceNet and OSEK. These features render the P8xC591 an excellent solution for insertion in a wide spectrum of CAN applications. The CAN transceiver and serial EEPROM on the phyCORE module provide additional CAN support by enabling storage of configuration data (network parameters). The board's standard memory configuration features 128 KB SRAM and 128 (to 512) KB Flash for storage of user code. PHYTEC FlashTools support in-system (ISP) programming of the Flash device. Free Chip-Select signals enable connectivity to external peripherals. The module communicates by means of an RS-232 or RS-485 interface, operates within a standard temperature range of 0 to 70 degrees C. and requires a low 5 V. power source.

phyCORE-87C51Mx2

The phyCORE-87C51Mx2 is populated by the Philips 89C51MC2 controller, which can access up to 2 MB Flash (standard 256 kB) and up to 1 MB (standard 256 KB) SRAM. The module is ideal for applications whose requirements exceed the memory space of the standard 8051, yet that can utilize code created within the 8051 instruction set. The phyCORE-87C51Mx2 offers two RS-232 interfaces, one of which can be configured as RS-485. The module also offers a serial EEPROM for storage of configuration data and a Real-Time Clock. The PLCC-socket of the controller enables easy connection of an emulator to the phyCORE-87C51Mx2.

phyCORE-89C51Rx2

The phyCORE-89C51Rx2 supports a variety of new Philips 44-pin 80C51-compatible microcontrollers featuring on-chip Flash with In-System Programming (ISP) capability. Other controller features include four 8-bit I/O ports; three 16-bit timer/event counters; a multi-source, four-priority-level nested interrupt structure; an enhanced UART and on-chip oscillator and timing circuits. The board's standard memory configuration features 32 KB external SRAM and 64 KB on-chip Flash for storage of user code. PHYTEC FlashTools support in-system (ISP) programming. Three free Chip-Select signals enable connectivity to external peripherals. The module communicates by means of an RS-232 interface (optionally configurable as RS-485), operates within a standard temperature range of 0 to 70 degrees C. and requires a low 5 V. power source.

phyCORE-89C66x

The phyCORE-89C66x supports a variety of new Philips 44-pin 80C51-compatible P89C66x microcontrollers featuring on-chip Flash with In-System Programming (ISP) capability. In contrast to microcontrollers offering on-chip OTP, on-chip Flash enables flexible on-board reprogramming during development, as well as upgrading via RS-232 of user code stored in hardware that is already implemented in the field. Other controller features include four 8-bit I/O ports; three 16-bit timer/event counters; a multi-source, four-priority-level nested interrupt structure; an enhanced UART and on-chip oscillator and timing circuits. The board's standard memory configuration features 32 KB external SRAM and 64 KB on-chip Flash (board populated witht eh P89C668) for storage of user code. PHYTEC FlashTools support in-system (ISP) programming. All applicable controller and logic signals extend to standard-width (2.54 mm.) multi-rowed pin headers located on two sides of the board, allowing it to be plugged like a "big chip" into target hardware applications. Three free Chip-Select signals enable connectivity to external peripherals. The module communicates by means of an RS-232 interface (optionally configurable as RS-485), operates within a standard temperature range of 0 to 70 degrees C. and requires a low 5 V. power source.

phyCORE-ADuC8xx

The phyCORe-ADuC812 supports the Analog Devices ADuC-812 (optionally ADuC814, ADuC816, ADuC824) microcontroller (TQFP-52 package). This controller features on-chip A/D as well as D/A converters, a reference voltage supply and a temperature sensor. The ADuC812 boasts an 8-channel 12-bit A/D converter and dual 12-bit D/A converters. The optional ADuC824 offers a 12-bit D/A as well as 24- and 16-bit A/D converters with a total of five channels. The on-chip non-volatile memory consists of 8 KB CODE Flash and 640 bytes of DATA Flash. This is augmented by 128 (to 512) KB external Flash and 128 KB (to 1 MB) SRAM. The included PHYTEC FlashTools support In-System-Programming of the external Flash memory via the RS-232 interface. for networking purposes, the board can be populated with an optional SJA1000 CAN controller and 82C251 CAN transceiver. An RTC9564 Real-Time Clock and 4 (to 16) KB EEPROM can be addressed over the I²C Bus. The module also offers port expansion via eight TTL level inputs and eight TTL level outputs. Three Chip-Select signals enable connectivity to external devices.

phyCORE-ARM7/AT91

Based on the Atmel AT91M55800A ARM7TDMI controller, the phyCORE-ARM7/AT91M55800A offers processing power combined with extremely low power consumption in a minimum form factor (60x53 mm). The AT91M55800A has a 32-Bit RISC architecture with a 16-bit command structure. A large number of internal register banks enable very fast command execution, making the controller especially suited for real-time applications. Up to 16 MB Flash and 8 MB SRAM in µBGA-housing populate the module as external memory. The on-board 82C900 twin CAN controller and TLE6250 CAN transceiver provide two fully configured 2.0B CAN interfaces, while a CS8900A Ethernet controller supports data transferred of 10 Mbit/s. The module comes complete with a JTAG-interface for download of user code and debugging purposes. All applicable logic signals are broken out at two dual-row high density (0.635 mm.) connectors.

phyCORE-ARM7/LPC229x

The phyCORE-ARM7/LPC229x module supports high-performance LPC2294, LPC2294 and LPC2200 ARM7TDMI-S™ processor-based devices from NXP.

The LPC2294 devices include up to four on-chip CAN nodes, and have other chip-level features which include emulation and embedded trace support, 256 KB Flash memory, an 8-channel 10-bit ADC, PWM channels and up to 9 external interrupt pins. The LPC2294 further boasts a 128-bit wide memory interface and a unique accelerator architecture enabling 32-bit code execution at maximum clock rate.

These features make the devices particularly suitable for automotive and industrial control applications as well as medical systems and fault-tolerant maintenance buses. With a wide range of additional serial communication interfaces, as well as a 10/100M-Bit Ethernet controller, the module is also suited for communication gateways and protocol converters. Flexible memory management of the phyCORE-LPC2294 enables the user to select a configuration based on the needs of their application, therefore optimizing costs.

phyCORE SBC modules are available in a variety of Rapid Development Kits that offer true rapid development solutions by providing all the necessary ingredients to jump start embedded designs. The kits include the phyCORE SBC module and Carrier Board, complete electronic documentation, schematics, demo applications, and third party industry-standard C compilers and embedded development environments for evaluation. A Rapid Development Kit for this board is available here.

phyCORE-AT89C51CC01

The phyCORE-AT89C51CC01 supports the AT89C51CC01, a member of the C51 X2 family of 8-bit microcontrollers dedicated to CAN network applications. While remaining fully compatible with the 80C51 it offers a superset of this standard microcontroller. In X2 mode a maximum external clock rate of 20 MHz reaches a 300 ns cycle time. Besides the Full 2.0B CAN controller, the T89C51CC01 provides 32 KB Flash memory supporting In-System Programming (ISP), 2 KB Boot-Flash, 2 KB EEPROM and 1.2 KB RAM. The on-chip memory is augmented by 32 KB of external SRAM and 128 KB Flash. The controller's CAN and ADC signals are available to the user at the edges of the board. The included PHYTEC FlashTools support In-System-Programming of the external Flash memory via the RS-232 interface. The Atmel FLIP utility supports programming of the on-chip Flash memory.

phyCORE-DS80C390

The phyCORE-390 is a Single Board Computer in subminiature dimensions. It is populated with the Dallas 8-bit, 80C51-compatible DS80C390 microcontroller. All ports and decoded interface signals extend to standard 2.54 pitch pin header rows. The phyCORE-390 offers 22-bit continuous memory support, 128 KB (to 1 MB) of external Flash memory with PHYTEC FlashTools download utility for in system (ISP) Flash programming and 128 KB (to 1 MB) of external SRAM. Two CAN transceivers and a serial EEPROM device provide additional CAN support, with the latter enabling storage of configuration data. The module communicates via an RS-232 or RS-485 serial interface which is jumper selectable. Included is an optional I2C Real Time Clock and optional battery back-up of the SRAM and RTC. The board requires a single 5V power supply for operation and Flash programming.

phyCORE-LPC3180

The phyCORE-ARM9/LPC3180 supports the industry's first 90nm ARM-9based microcontroller. The new 32-bit MCU high-performance, low power LCP3180 ARM926EJ-S device from NXP Semiconductors (founded by Philips) is the only ARM9 microcontroller that provides a vector floating-point co-processor and integrated USB OTG, as well as the ability to operate in ultra-low-power mode down to 0.9V. The on-board MMU supports major operating systems, including Linux which is the leading major embedded OS. Other chip-level features include 7 UARTs, SPI, I2C, a real-time clock with a separate power domain, and NAND Flash and DDR memory controllers. These features make the devices particularly suitable for automotive and industrial control applications as well as medical systems. * Single Board Computer in subminiature dimensions (60 x 53 mm) according to low EMI phyCORE specifications * NXP Semiconductors (founded by Philips) LPC3180 ARM926EJ-S controller (208 MHz) with VFP9 hardware vector floating-point coprocessor for speed and efficiency as well as 2x SPI, 2x I²C, 2x PWM, MMU and 3-channel/10-bit ADC * Controller and board-level signals extend to two high-density (0.635 mm) 100-pin Molex connectors on underside of SBC * SDRAM: 16 to 64 MB synchronous SDRAM, max. access time of 10ns, 32-bit organization * Flash: 16 to 128 MB NAND-Flash in 8-bit mode * Serial: 1 to 32 KB I²C-EEPROM * On-chip Real-Time Clock with Alarm function and battery back-up * On-chip USB Host/Device interface (can be used as USB-OTG in conjunction with external ISP1301 USB-OTG device) * 7x UARTs, 3x of which at RS-232 level (2x standard, 1x High-Speed with Handshake) * JTAG signals extend to edge connector * Industrial temperture range (-40°...+85°C)

phyCORE-LPC3250

The phyCORE-LPC3250 is an ARM-9 based, small form factor, OEMable module populated with the NXP LPC3250. State-of-the-art power management, Vector Floating Point Unit (VFP), and rich peripherals such as USB OTG, Ethernet, and integrated LCD controller make this module the ideal candidate for embedded applications requiring high performance and low power consumption. The on-board MMU supports major operating systems, including Linux and Windows Embedded CE. Other chip-level features include 7 UARTs, SPI, I2C, a real-time clock with a separate power domain, and NAND Flash and DDR memory controllers. These features make the devices particularly suitable for automotive and industrial control applications as well as medical systems. The phyCORE SBC module is designed to plug into a PHYTEC Carrier Board that provides the I/O connectors as well as any other interface circuitry not provided on the phyCORE module itself. The phyCORE module, combined with the PHYTEC Carrier Board, provides a platform to jump start embedded designs and propel concept to prototype and finished product.

phyCORE-ST10F168

The phyCORE-ST10F168 supports high-end 16-bit controllers from STMicroelectronics featuring on-chip CAN and Flash. The module is intended for use in memory-intensive applications and in driving a CAN-bus interface. Smaller than a credit card (55 by 47 mm.), the standard board is populated with the ST10F168, the module supports an additional 256 KB of on-chip Flash. PHYTEC FlashTools enable easy on-board download of user code. All controller signals and ports extend to 2x100-pin rows of high-density (0.635) Molex connectors aligning two edges of the board. These pins provide a 16-bit bi-directional I/O port, 64+ free port lines, a 16-channel ADC with 10-bit resolution and two RS-232 interfaces. The ST10F168 supports a single CAN interface. A special feature of the board is the ability to reroute the controller CAN signals from the address lines, enabling direct external addressing of up to 16 MB address space. The phyCORE operates in a standard temperature range from 0 to 70 degrees C. (with extended range from -40 to 85 degrees C.) and requires a low 250 mA. power source.

phyCORE-ST10F269 HS/E

The phyCORE-ST10F269 HS/E (High-Speed Ethernet) supports various 144-pin devices in MQFP package from STMicroelectronics. The board offers up to 1 MB external SRAM, 2 MB external Flash and supports on-board in-system (ISP) Flash programming. If populated with the ST10F269, the module offers an additional 256 KB on-chip Flash. ST10 devices provide 111 I/O-lines and a supplemental UART for a second serial (modem-capable) interface. The Cirrus Logic C58900A controller enables Ethernet communication with a transmission rate of 10 Mbit/s. The minimal form factor and enhanced EMI characteristics of the phyCORE render the module an excellent subassembly to drive OEM applications.

phyCORE-XC161

The phyCORE-XC161 belongs to PHYTEC's phyCORE Single Board Computer module family and supports the XC16x controllers from Infineon in TQFP-144-50 housing. The Flash can easily be programmed on board. Support of the XC16x family "Single Chip Mode" provides the user with maximum flexibility for expansion via external peripherals. An additional feature is the possibility of connecting the CAN interface from within the address area, whereby direct external addressing of up to 16 MB address space is enabled. On-Chip Full 2.0B CAN, 99 I/O lines and two serial interfaces are additional board features. Data transfer rates of 10Mbit/s are possible with the on-board CS8900 Ethernet controller from Cirrus Logic. All controller and peripheral signals extend to two 100-pin, high-density Molex connectors on the underside of the phyCORE-XC161.

phyCORE-XC167

The phyCORE-XC167 belongs to PHYTEC's phyCORE Single Board Computer module family and supports the XC16x controllers from Infineon in TQFP-144-50 housing. The Flash can easily be programmed on board. Support of the XC16x family "Single Chip Mode" provides the user with maximum flexibility for expansion via external peripherals. An additional feature is the possibility of connecting the CAN interface from within the address area, whereby direct external addressing of up to 16 MB address space is enabled. On-Chip Full 2.0B CAN, 99 I/O lines and two serial interfaces are additional board features. Data transfer rates of 10Mbit/s are possible with the on-board CS8900 Ethernet controller from Cirrus Logic. All controller and peripheral signals extend to two 100-pin, high-density Molex connectors on the underside of the phyCORE-XC167.