Verification of Complex Analog and RF IC Designs

Chang, Henry; Kundert, Ken

doi:10.1109/jproc.2006.889384

Cited by 37 publications

(19 citation statements)

References 19 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Also, another disadvantage of designs at this level is that they are not supported by transistor level simulators, preventing their cosimulation with transistor level designs [9]. Co-simulations of transistor level designs with higher design levels are desired, because they allow the designer to implement only the critical design areas at the transistor level, while representing the non-critical design areas at higher design levels, speeding up MS-RF-IC verifications.…”

Section: Safetymentioning

confidence: 99%

“…Transistor level simulations also have been used to verify analog portions of wireless transceivers. However, due to the complexity (e.g., thousands of modes of operations and settings) of modern MS-ICs, transistor level simulations of a single IC mode can sometimes take a week or more, which may result highly impractical [9].…”

Section: Safetymentioning

confidence: 99%

“…An MS system verification methodology was proposed by Chang and Kundert [9], in order to reduce the time to reach an MS-IC design that meets target specifications, and to reduce the risk of MS-IC functional failures. This methodology suggests the use of hardware description languages (HDL) and a mixed-signal simulator, for the RTL design and functional verification of MS systems.…”

Section: Rf-register Transfer Level (Rtl) Designmentioning

confidence: 99%

“…An advantage of being able to verify an HDLbased RTL design of an MS system is that functional errors can be detected early in the IC development process, which can save money and time. These savings can occur since functional error corrections may be more difficult and time consuming at the transistor level design [9], and IC re-spins can be quite expensive nowadays [8]. Also, another advantage of RTL designs is that they can ease the re-use of MS-IC designs.…”

Section: Rf-register Transfer Level (Rtl) Designmentioning

confidence: 99%

See 3 more Smart Citations

Performance of a high-speed transcutaneous link with error correction coding

Toribio

Winstead

2013

2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

View full text Add to dashboard Cite

A Register Transfer Level (RTL) design that integrates a figure-8 multi-band inductive link (MIL), a bi-level pulse harmonic modulation (PHM) system, and a Gallager A decoder is presented and verified. Integrating this MIL with a PHM system can lead to optimizing power efficiency, data rate, and transmitter power consumption in near field transcutaneous wireless communication systems for cortical implants (CI). Also, a technique to increase the data rate of PHM systems based in multi-level transmission (MLT) is presented. MLT is an attractive solution to increasing data rates in PHM systems while meeting power consumption constraints, since it does not require increasing the frequency of the harmonics generated in the PHM receiver. Verilog Analog Mixed Signal (AMS) was used to verify these systems. The distance between external and implanted coils was modeled to be 10 mm.From the power interference characterization of the bi-level system, it was observed that for every value of the coupling coefficient between the power transmitter coil and data receiver coil (k 14 ), there is a different comparator reference voltage that can minimize the bit error rate (BER) of the system and optimize decoder performance. Moreover, it is shown that as k 14 increases, this optimal reference voltage also increases. Therefore, it is expected that a control system that could adapt the comparator reference voltages to changes in (k 14 ), could enhance robustness of PHM systems against factors that can increase MIL power iv interference, such as misalignments. From the verification of the MLT technique, it was observed that the optimal delay between initiation and suppression pulses (t d ) of a PHM system varies with respect to initiation pulse amplitudes, contrary to what had been stated in the past in previous PHM system verifications. Furthermore, it is concluded that, unless the pulse pattern generator (PPG) is designed to vary t d according to the initiation pulse transmitted, MLT-based PHM systems would be too vulnerable to non-idealities, such as noise and misalignments, preventing its feasibility. From the transmitter (TX) clock jitter characterizations, it was concluded that as the PHM levels of transmission increase, systems become more sensitive to jitters. Finally, the Gallager A decoder was found powerful in enhancing the robustness of PHM systems against power interference, TX clock jitter, and noise. Cortical implants (CI) can be used in medicine to treat neurological disorders, and to serve as substitutes of damaged organs in the nervous system. Currently, active research is being developed in the wireless data and power transfer to CIs, in order to avoid frequent surgical interventions to replace batteries and potential paths of infection due to wires breaching the skin. In this paper, we consider performance optimization strategies for a pulse-based wireless link that have been proposed recently. We consider two enhancements that may allow for increased throughput in this system. First, a low-power error-correcting ...

show abstract

Section: Safetymentioning

confidence: 99%

Section: Safetymentioning

confidence: 99%

Section: Rf-register Transfer Level (Rtl) Designmentioning

confidence: 99%

Section: Rf-register Transfer Level (Rtl) Designmentioning

confidence: 99%

See 2 more Smart Citations

Performance of a high-speed transcutaneous link with error correction coding

Toribio

Winstead

2013

2013 35th Annual International Conference of the IEEE Engineering in Medicine and Biology Society (EMBC)

View full text Add to dashboard Cite

show abstract

“…This requires solving problems like unacceptable simulation time and the need for tremendous computation power, especially for the verification of RF front-ends with very high carrier frequencies [2], [3]. Therefore, the modeling of the subsystems and circuits becomes an indispensable task for the functional verification flow [4]. Hardware description languages offer the possibility to model the behavior of the circuits, reducing the number of equations by substituting the abstract coherences between the components with simpler mathematical descriptions of the circuits' behavior.…”

Section: Introductionmentioning

confidence: 99%

Formal approaches to analog circuit verification

Barke

Grabowski

Graeb

et al. 2009

2009 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition

View full text Add to dashboard Cite

Abstract-For a speed-up of analog design cycles to keep up with the continuously decreasing time to market, iterative design refinement and redesigns are more than ever regarded as showstoppers. To deal with this issue, referred to as design and verification gap, the development of a continuous and consistent verification is mandatory. In digital design, formal verification methods are considered as a key technology for efficient design flows. However, industrial availability of formal methods for analog circuit verification is still negligible despite a growing need. In recent years, research institutions have made considerable advances in the area of formal verification of analog circuits. This paper presents a selection of four recent approaches in analog verification that cover a broad scope of verification philosophies.

show abstract

Analog Verification

Kundert¹,

Chang²

2011

Simulation and Verification of Electronic and Biological Systems

View full text Add to dashboard Cite

Verification of Complex Analog and RF IC Designs

Cited by 37 publications

References 19 publications

Performance of a high-speed transcutaneous link with error correction coding

Performance of a high-speed transcutaneous link with error correction coding

Formal approaches to analog circuit verification

Analog Verification

Contact Info

Product

Resources

About