Circuit model for the GaAs m.e.s.f.e.t. valid to 12 GHz

A new equivalent circuit is given for the GaAs m.e.s.f.e.t., which includes resistive loss in the feed back elements. The circuit values are given for several 1 ?m-gate GaAs m.e.s.f.e.t.s. A method for fitting s12 to the measured data is described. Finally, the gain and stability factor of several GaAs m.e.s.f.e.t.s. are extrapolated to 24 GHz from the present model.     

7.9?8.4 GHz GaAs m.e.s.f.e.t. amplifier

A 4-stage balanced GaAs m.e.s.f.e.t. amplifier has been developed for the 7.9?8.4 GHz satellite-communication frequency band. Linear gain of 26±0.5dB and 150 mW power at 1 dB compression were obtained across the design band. The small-signal gain, phase linearity, group delay and noise figure are described as a function of frequency. Large-signal gain saturation, 3rd-order intermodulation distortion, gain and phase against temperature and a.m.-to-p.m. conversion data are also presented.     

10 GHz/10 W internally matched flip-chip GaAs power f.e.t.s

A flip-chip GaAs power f.e.t. delivering 10 W power output with 3 dB gain has been realised at 10 GHz by using a newly developed internal matching technique, in which the f.e.t. chips are directly connected to the lumped capacitors in the matching networks.     

Low-noise GaAs m.e.s.f.e.t.s

GaAs m.e.s.f.e.t.s with optimum noise figures of 1.6 dB at 6 GHz have been fabricated by projection photolithography. An equation has been developed for the calculation of optimum noise figure which gives good agreement between calculated and measured values.     

High-speed 1 ?m GaAs m.e.s.f.e.t.

By minimising parasitic series resistances, a GaAs m.e.s.f.e.t. with 1 ?m gate length was fabricated, possessing the highest known r.f. power gain, measured up to 18 GHz, for GaAs m.e.s.f.e.t.s.     

Performance of GaAs power m.e.s.f.e.t.s

Power performance results at 4 GHz are summarised for GaAs m.e.s.f.e.t.s ranging in size from 4 to 16 mm gate periphery. A double-chip 16 mm unit operated at 24 V source-drain bias produced 13.5 W with 3 dB gain and 10.7 W with 8.1 dB gain. Although lack of perfect power and gain scaling is observed, the degradation in output power of the 16 mm devices was only 1 dB compared to the smaller devices.     

High-efficiency GaAs m.e.s.f.e.t. amplifiers

High-efficiency c.w. amplification with GaAs m.e.s.f.e.t.s under class-B conditions has been demonstrated. Power added efficiencies as high as 68% at 4 GHz and 41% at 8 GHz have been achieved. Two-tone tests were carried out at 4 GHz. The power added efficiencies at the 3rd-order intermodulation levels of ?20, ?25 and ?30 dB were 49, 40 and 35% respectively.     

Avalanche noise in GaAs m.e.s.f.e.t.s

Instabilities in the d.c. characteristics of GaAs m.e.s.f.e.t.s for drain to source voltages greater than 4 V. believed to be due to reloading of traps in the interface between active layer and bulk material, or gunn-domain formation, seem to have their origin in avalanche breakdown of the back diode under the drain contact. Microplasma switching, vertical to the active layer, strongly modulates the drain current producing large broadband noise power.     

Substrate conduction in GaAs m.e.s.f.e.t.s

Substrate currents in a gateless GaAs m.e.s.f.e.t. have been measured at d.c, 0.9 MHz and 2 GHz. The results are consistent with the assumption of substrate conduction at high frequencies and active-layer conduction alone at low frequencies.     

Dual gate GaAs m.e.s.f.e.t. phase shifter with gain at 12 GHz

A dual gate m.e.s.f.e.t. phase shifter is described with 4 dB insertion gain at 12 GHz and more than 100° linear continuous phase shift as a function of the d.c. voltage applied to the controlling gate electrode.     

Large signal GaAs m.e.s.f.e.t. model and distortion analysis

A simple large signal model, derived from small signal measurements over a range of bias points, is presented for a 2 ?m gate length GaAs m.e.s.f.e.t. Its accuracy is verified by comparing model-predicted second harmonic distortion via time domain and Volterra analyses, with measurements to input frequencies of 4.5 GHz.     

11 GHz and 12 GHz multiwatt internal matching for power GaAs f.e.t.s

Multiwatt internal-matching techniques for multichip power GaAs f.e.t.s at 11 GHz and 12 GHz bands have been developed, adopting a lumped-element input circuit and a semidistributed output circuit. The internally matched device for the 11 GHz band exhibits 4 W power output with 3.4 dB associated gain, and the 12 GHz device 3.6 W power output with 3 dB associated gain.     

Performance of GaAs m.e.s.f.e.t. oscillators in the frequency range 8?25 GHz

Performance results of microstrip GaAs m.e.s.f.e.t. oscillators operating in the frequency range 8?25 GHz are reported. It is shown that output powers as high as 500 mW and efficiencies as high as 45% can be achieved.     

High-yield self-alignment method for submicrometre GaAs m.e.s.f.e.t.s

A high-yield self-alignment technique for submicrometer GaAs m.e.s.f.e.t.s is described. This method allows the production of submicrometre gate lengths and source-drain spacings by means of standard contact photolithography without requiring a particularly fine geometry on the masks. A 0.5 ?m long gate and a source-drain spacing of 2 ?m were obtained.     

Femtojoule logic circuit using normally-off GaAs m.e.s.f.e.t.s

Experimental results are reported on the speed/power performance of normally-off-type GaAs-m.e.s.f.e.t. logic circuits, using an integrated 15-stage ring oscillator as a test circuit. A power consumption as low as 1-5 ?W, corresponding to a power-delay product of 1.6 fJ, was obtained. Conversely, a propagation delay time of 650 ps was measured for a power consumption of 20 ?W per gate.     

GaAs gigabit logic circuits using normally-off m.e.s.f.e.t.s

Normally-off GaAs m.e.s.f.e.t. logic circuits fabricated by electron beam lithography have exhibited excellent high speed switching characteristics. The highest switching speed evaluated from a 15-stage ring oscillator is 30 ps per gate with a power dissipation of 1.9 mW. Binary frequency dividers have been fabricated with D-type flip-flops operating up to 3 GHz. A divide-by-eight counter has also operated at 2.5 GHz.     

Modelling of Gunn-domain effects in GaAs m.e.s.f.e.t.s

GaAs m.e.s.f.e.t. [S22] values larger than unity have been measured from 1 to 10 GHz in the region where the ID/VD curves display a negative slope. An explanation of this phenomenon is proposed in terms of Gunn-domain formation. An equivalent-circuit model which includes this effect is presented and discussed.     

X and Ku band GaAs m.e.s.f.e.t.

A GaAs Schottky-barrier f.e.t. (m.e.s.f.e.t.) with a 1 ?m gate has been built, which is suitable for X band and Ku band applications. The unilateral power gain over the X band is above 9 dB and the noise figure is only 5 dB at 10 GHz.     

Optimised doping profiles for speed-up of GaAs m.e.s.f.e.t.s

Simulation of m.e.s.f.e.t. logic cell shows that discharging of the gate depletion is significantly slower than the charging process. The transient response with the charging/discharging is analytically connected to arbitrary doping profiles. Specific profiles with a doping peak near the substrate boundary can reduce this discharging delay remarkably.     

Alumina microstrip GaAs f.e.t. 11 GHz oscillator

A small, lightweight 11 GHz f.e.t. oscillator has been developed. An output power of 10 mW with an efficiency of 10% was easily produced using a GaAs f.e.t. designed for small-signal amplifier applications. Its low power consumption makes it a suitable low-noise source for integrated-receiver applications.