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www.us-tech.com XJTAG Expands In-System XJFlash Programming Capabilities


Cambridge, UK — XJTAG has brought its high-speed in-system pro- gramming (ISP) technology XJFlash to memory devices connected to the processor subsystem of dual-ARM Cortex-A9-based FPGAs.


the FPGA. Configuring these memo- ries in both development and produc- tion environments is normally a slow and complex process. With XJFlash these memories can now be configured simply and at


ured without having to reprogram the entire device, while also minimiz- ing the erase time when regions of a device are already blank. XJFlash can be used wherever


XJTAG can — as part of a stand- alone XJTAG test system, or fully- integrated into third-party test exec- utives, such as LabVIEW, or in sys- tems that also use other automated


test equipment. Contact: XJTAG, St. John’s In-


novation Centre, Cowley Road, Cambridge CB4 0DS, UK % +44-0- 1223-223007 fax: +44-0-1223-223009 E-mail: enquiries@xjtag.com Web: www.xjtag.com


See at electronica, Hall A1 Booth 470


Scheugenpflug Intros Piston XJFlash now supports ARM Cortex-A9-based SoCs. According to the company, users


can now achieve programming times up to 20 times faster than existing solutions when configuring memory attached to the processor subsystems of FPGA SoCs, including Xilinx Zynq and the Altera Cyclone V, which con- tain ARM Cortex-A9 processors. The use of FPGAs with inte-


grated processor subsystems is in- creasing. While these subsystems are fully integrated into the FPGA fab- ric, they have their own, dedicated, external, non-volatile program mem- ory, connected to the physical pins of


high speed through the JTAG port of the FPGA, without the need for any additional PCB connections. XJFlash is now able to access


and configure memory devices con- nected to a wider range of FPGAs. This significantly decreases the time taken to configure onboard memory during development, production and rework.


Support for the ARM Cortex-


A9-based SoCs also extends to par- tial reconfiguration and optimized erase. This enables memory devices to be partially erased and reconfig-


Metering Dispensing System Wiesbaden, Germany — Scheugen - pflug has introduced a new piston metering dispensing system, the Dos TCA. The Dos P016 TCA piston me- tering system has been optimized for highly-filled thermally-conductive materials and is able to dispense Dow Corning® TC-4515 thermal gap filler. Compared to the Dos P stan- dard model the new dispenser achieves up to three times higher flow rates — at consistently high me- tering accuracy. The system’s precision metering


cylinders allow the output of repro- ducibly accurate material volumes and in 2C materials provides con- stant mixing ratios at all times. Dow Corning’s TC-4515 ther-


mally conductive gap filler is a new material for the transportation elec- tronics industry, further completing the company’s gap filler portfolio with a lower thermal conductive so-


vertical stability after cure. Contact: Scheugenpflug AG,


Gewerbepark 23, 93333


Neustadt/Donau, Germany % +49-9445-9564-295 E-mail: vertrieb.de@scheugenpflug.de Web: www.scheugenpflug.de


See at electronica, Hall A2 Booth 231


lution for thermal conductivity of 1.5 W/m°K. The gap filler is designed to im-


prove dispensability, reduce abra- siveness and provide stable perform- ance for reliable electronics in harsh automotive under-the-hood applica- tions.


The material is a soft, vibration


dampening, two-part silicone with excellent thixotropic properties that enable it to be dispensed easily, avoid slumping on vertical surfaces during assembly and maintain its


October, 2016


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