A proposed simulation technique to study the series resistance and related millimeter-wave properties of Ka-band Si IMPATTs from the electric field snapshots
Abstract:A large-signal model and a simulation technique based on non-sinusoidal voltage excitation are used to obtain the electric field snapshots from which the series resistance and related high-frequency properties of a 35 GHz Silicon Single-Drift Region (SDR) Impact Avalanche Transit Time (IMPATT) device have been estimated for different bias current densities. A novel method is proposed in this paper to determine the parasitic series resistance of a millimeter-wave IMPATT device from large-signal electric field s… Show more
“…1 is used for the L-S simulation of DDR IMPATT device because of the physical phenomena taking place in the semiconductor bulk along the symmetry axis of the mesa structure of IMPATT devices. The fundamental time- and space-dependent device equations, such as Poisson's equation (equation (1)), continuity equations (equations (2) and (3)) and current density equations (equations (4) and (5)) involving mobile space charge in depletion layer are simultaneously solved under L-S conditions with appropriate boundary conditions by using a DEFM simulation method [21–23]. The fundamental device equations are given by Fig.…”
Section: L-s Simulation Techniquementioning
confidence: 99%
“…In the present paper, the authors have made an attempt to obtain the upper cut-off frequency limit of DDR Si IMPATTs through an avalanche response time based simulation approach [17–20]. An L-S simulation technique based on non-sinusoidal voltage excitation (NSVE) model [21–23] is developed and simulation is carried out to study L-S characteristics of DDR IMPATTs based on Si designed to operate at different mm-wave and terahertz (THz) frequencies up to the limiting frequency of IMPATT operation for DDR Si IMPATTs obtained from avalanche response time based simulation, i.e. up to 0.5 THz.…”
Large-signal (L-S) characterization of double-drift region (DDR) impact avalanche transit time (IMPATT) devices based on silicon designed to operate at different millimeter-wave (mm-wave) and terahertz (THz) frequencies up to 0.5 THz is carried out in this paper using an L-S simulation method developed by the authors based on non-sinusoidal voltage excitation (NSVE) model. L-S simulation results show that the device is capable of delivering peak RF power of 657.64 mW with 8.25% conversion efficiency at 94 GHz for 50% voltage modulation; whereas RF power output and efficiency reduce to 89.61 mW and 2.22% respectively at 0.5 THz for same voltage modulation. Effect of parasitic series resistance on the L-S properties of DDR Si IMPATTs is also investigated, which shows that the decrease in RF power output and conversion efficiency of the device due to series resistance is more pronounced at higher frequencies especially at the THz regime. The NSVE L-S simulation results are compared with well established double-iterative field maximum (DEFM) small-signal (S-S) simulation results and finally both are compared with the experimental results. The comparative study shows that the proposed NSVE L-S simulation results are in closer agreement with experimental results as compared to those of DEFM S-S simulation.
“…1 is used for the L-S simulation of DDR IMPATT device because of the physical phenomena taking place in the semiconductor bulk along the symmetry axis of the mesa structure of IMPATT devices. The fundamental time- and space-dependent device equations, such as Poisson's equation (equation (1)), continuity equations (equations (2) and (3)) and current density equations (equations (4) and (5)) involving mobile space charge in depletion layer are simultaneously solved under L-S conditions with appropriate boundary conditions by using a DEFM simulation method [21–23]. The fundamental device equations are given by Fig.…”
Section: L-s Simulation Techniquementioning
confidence: 99%
“…In the present paper, the authors have made an attempt to obtain the upper cut-off frequency limit of DDR Si IMPATTs through an avalanche response time based simulation approach [17–20]. An L-S simulation technique based on non-sinusoidal voltage excitation (NSVE) model [21–23] is developed and simulation is carried out to study L-S characteristics of DDR IMPATTs based on Si designed to operate at different mm-wave and terahertz (THz) frequencies up to the limiting frequency of IMPATT operation for DDR Si IMPATTs obtained from avalanche response time based simulation, i.e. up to 0.5 THz.…”
Large-signal (L-S) characterization of double-drift region (DDR) impact avalanche transit time (IMPATT) devices based on silicon designed to operate at different millimeter-wave (mm-wave) and terahertz (THz) frequencies up to 0.5 THz is carried out in this paper using an L-S simulation method developed by the authors based on non-sinusoidal voltage excitation (NSVE) model. L-S simulation results show that the device is capable of delivering peak RF power of 657.64 mW with 8.25% conversion efficiency at 94 GHz for 50% voltage modulation; whereas RF power output and efficiency reduce to 89.61 mW and 2.22% respectively at 0.5 THz for same voltage modulation. Effect of parasitic series resistance on the L-S properties of DDR Si IMPATTs is also investigated, which shows that the decrease in RF power output and conversion efficiency of the device due to series resistance is more pronounced at higher frequencies especially at the THz regime. The NSVE L-S simulation results are compared with well established double-iterative field maximum (DEFM) small-signal (S-S) simulation results and finally both are compared with the experimental results. The comparative study shows that the proposed NSVE L-S simulation results are in closer agreement with experimental results as compared to those of DEFM S-S simulation.
“…The time and space dependent device equations i.e., Poisson's equation, continuity equation and current density equation are simultaneously solved under large-signal condition subject to appropriate boundary conditions. A doubleiterative simulation method [9][10][11][12][13] based on 1-D finite difference method (FDM) is used for this purpose. The device equations used in the simulation are given by …”
Section: Large-signal Model and Simulation Methodsmentioning
confidence: 99%
“…The large-signal program [9][10][11][12][13] is first run for a complete cycle (i.e. 0 ≤ ωt ≤ 2π ) and then repeated for consecutive cycles to ensure the oscillation stability.…”
Section: Large-signal Model and Simulation Methodsmentioning
confidence: 99%
“…The large-signal properties of DAR Si diode are obtained from indigenously developed large-signal simulation software based on NSVE model [9][10][11][12][13]. The simulation involves simultaneous numerical solution of the both time and space dependent device equations subject to appropriate boundary conditions at the depletion layer edges.…”
A large-signal method based on non-sinusoidal voltage excitation model is used to study the DC and RF characteristics of Double Avalanche Region (DAR) Silicon Transit Time diode. A large-signal simulation program based on drift-diffusion model is developed for this study. The simulation results show the existence of several distinct negative conductance bands in the admittance characteristics separated by positive conductance. Thus the DAR device is capable of delivering RF power not only at the design frequency but also at several frequency bands higher than the design frequency band in the mm-wave regime. A comparative study with DDR Si device designed to deliver RF power at a particular mm-wave frequency band shows that DAR Si device is capable of delivering significantly higher RF power not only at the designed mm-wave frequency band, but also at higher frequency bands.
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