A 20 GHz 8 bit multiplexer IC implemented with 0.5 μm WNx/W-gate GaAs MESFET's

An ultrahigh-speed 8 bit multiplexer (MUX) has been developed for future-generation optical-fiber communication systems having a data rate of 20 Gb/s. This IC was fabricated using a 0.5 μm WN_x/W-gate GaAs MESFET process based on optical lithography, ion implantation, and furnace annealing for good reproducibility and high throughput. The WN_x/W bilayer gate has a low sheet resistance, improving the circuit high frequency performance. To attain 20 GHz operation, advanced circuit techniques for the source-coupled FET logic (SCFL) were introduced. A cross coupled source-follower (CCSF) was developed mainly for the highest speed buffers to enhance the bandwidth. The first-stage T-type flip-flop was designed with optimization techniques and operated up to 21.1 GHz     

An 8-b slice GaAs bus logic LSI for a high-speed parallelprocessing system

An 8-b slice GaAs bus logic LSI (BL) has been developed for a high-speed interconnection network in a multiple-instruction multiple-data stream (MIMD) parallel processing system. The BL has been designed using a novel standard-cell approach called the building-cell methodology, which leads to a high integrated density of 25000 devices in a 7×7-mm² chip. The BL consists of 3376 logic gates and a 76-b dual-port register file (RF), which has as a new function a multi-address read/write operation for efficient data transfer. The BL was fabricated by a 0.8-μm WN_x gate LDD (lightly doped drain) MESFET process, and fully functionally tested with an average yield of 20%. A 10-ns cycle time operation was achieved with a power dissipation of 5.5 W. This result reveals that a network with 256 GaAs BLs and 64 processor units can realize a maximum data transfer rate of 2.56 Gbyte/s     

Measurement of acetylcholine released from rabbit detrusor smooth muscle using HPLC with electro-chemical detection coupled with microdialysis procedure

We measured the amount of acetylcholine (ACh) released from rabbit detrusor smooth muscles induced by electrical field stimulation (EFS) using microdialysis procedure. The dialysis probe was inserted through the detrusor muscle strip and was continuously perfused with a Ringer solution containing physostigmine sulfate, at a rate of 2 microl/min. The strip was suspended in an organ bath filled with the modified Krebs-Henseleit solution and then EFS was delivered. The isometric force was recorded and monitored in each muscle preparation. The dialysates were collected every 10 min. ACh was determined by a high performance liquid chromatography with electro-chemical detection. The contraction of the muscle strip and ACh release induced by EFS were increased in a frequency and duration dependent manner. There were some differences between frequency response curves of contraction and frequency dependent ACh release. In the contractile response, the maximum contractions were observed at lower frequencies, while ACh releases reached the maximum at higher frequencies. There was a significant, but not simple correlation between EFS-induced contraction and ACh release. The results suggest that this new method is useful to investigate the ACh release from rabbit detrusor smooth muscles, and that other neurotransmitters than ACh possibly contribute to EFS-induced contraction.