Sensors for built-in alternate RF test

Abdallah, L.; Stratigopoulos, Haralampos-G.; Kelma, Christophe; Mir, Salvador

doi:10.1109/etsym.2010.5512783

Cited by 40 publications

(23 citation statements)

References 16 publications

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“…Note that the logic levels of the LFSRs are always consistent with that of buck converter's internal logic. Optimization of the LFSR structure is performed via genetic optimization similar to that discussed in [5][6][18][19][20][21] and produces an LFSR that generates perturbations in such a way that the response of the converter to the applied perturbations are maximally correlated with the specifications of the converter under multi-parameter statistically representative process variations.…”

Section: Loop Perturbationsmentioning

confidence: 99%

“…In this context, techniques such as self-learning based adaptation [12][13], power-conscious tuning [14] and system level testing and tuning [15][16][17] concepts have been developed. Although a self-tuning approach based on alternative built-in self-test for RF devices has been developed in the past to reduce testing cost and testing time [18][19][20][21], the work reported in this paper develops, for the first time, a testing and self-tuning methodology that avoids the hazards (voltage spikes) associated with standard testing procedures while providing guarantees for the same.…”

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confidence: 99%

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A self-tuning architecture for buck converters based on alternative test

Wang

Blanchard

Estella

et al. 2014

2014 International Test Conference

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This paper proposes a self-tuning architecture for buck converters based on a modified alternative "safe" testing approach. It avoids voltage spikes caused by conventional full load testing and provides measurements with strong statistical correlation with the DUT's specifications. The measurements are sampled by a 5-bit ADC and analyzed by on-chip resources for evaluating the DUT specifications and predicting the corresponding values of buck converter tuning knobs to compensate for process variations when standard perfonnances are not met. Thus, the proposed methodology enables self-test and self-tuning of buck converters during production test without the risk of DUT damage during standard production test. The causes of voltage spikes during conventional full load test are discussed both analytically and numerically and the working mechanism of an alternative test procedure is developed. This proposed technique is demonstrated through both simulation and hardware validation experiments.

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Section: Loop Perturbationsmentioning

confidence: 99%

mentioning

confidence: 99%

A self-tuning architecture for buck converters based on alternative test

Wang

Blanchard

Estella

et al. 2014

2014 International Test Conference

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“…The transistor-level structure of this current sensor can be seen in the blow-out part of Figure 2. The output of the BICS is a high frequency signal which we convert to a DC voltage through a CMOS envelope detector [10]. Both the current sensor and envelope detector are CMOS designs so that they are compatible with other parts of the circuit.…”

Section: B On-chip Trust Evaluation Resourcesmentioning

confidence: 99%

Post-deployment trust evaluation in wireless cryptographic ICs

Jin¹,

Maliuk²,

Makris³

2012

2012 Design, Automation &Amp; Test in Europe Conference &Amp; Exhibition (DATE)

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The use of side-channel parametric measurements along with statistical analysis methods for detecting hardware Trojans in fabricated integrated circuits has been studied extensively in recent years, initially for digital designs but recently also for their analog/RF counterparts. Such post-fabrication trust evaluation methods, however, are unable to detect dormant hardware Trojans which are activated after a circuit is deployed in its field of operation. For the latter, an on-chip trust evaluation method is required. To this end, we present a general architecture for post-deployment trust evaluation based on on-chip classifiers. Specifically, we discuss the design of an on-chip analog neural network which can be trained to distinguish trusted from untrusted circuit functionality based on simple measurements obtained via on-chip measurement acquisition sensors. The proposed method is demonstrated using a Trojan-free and two Trojan infested variants of a wireless cryptographic IC design, as well as a fabricated programmable neural network experimentation chip. As corroborated by the obtained experimental results, two current measurements suffice for the on-chip classifier to effectively assess trustworthiness and, thereby, detect hardware Trojans that are activated after chip deployment.

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“…Different sensors that extract RF power and convert it into a low-frequency signal for BIST purposes are available in the litterature [11][12] [13]. We have developed an envelope detector, with a very simple architecture, based on the following design constraints: (a) minimum silicon area overhead, (b) high input impedance in the frequency range of interest to avoid undesired loading of the CUC, (c) high dynamic range suitable for testing different on-chip CUCs, and (d) wide band of operation to monitor CUCs that work at different frequencies involved in the system.…”

Section: Envelope Detectormentioning

confidence: 99%

Adaptive Logical Control of RF LNA Performances for Efficient Energy Consumption

Khereddine

Abdallah

Simeu

et al. 2012

VLSI-SoC: Forward-Looking Trends in IC and Systems Design

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Abstract. This work presents a new approach for controlling power consumption in RF devices. The approach is based on the definition of application-dependent performance modes for power hungry RF circuits and a logical control strategy that adjusts the power supply of each circuit to the mode required by the application. The control strategy uses embedded sensors, a recursive parameter identification approach and regression models for performance prediction, while demanding minimum embedded resources for computation. The control strategy is robust with respect to circuit parametric deviations due to the manufacturing process or ageing mechanisms. The strategy is illustrated for the case of an RF LNA using envelop detectors as embedded sensors. Simulation results of the control strategy at the transistor-level illustrate the energy savings that can be obtained for an example application.

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Sensors for built-in alternate RF test

Cited by 40 publications

References 16 publications

A self-tuning architecture for buck converters based on alternative test

A self-tuning architecture for buck converters based on alternative test

Post-deployment trust evaluation in wireless cryptographic ICs

Adaptive Logical Control of RF LNA Performances for Efficient Energy Consumption

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