Eduardo Aldrete-Vidrio scite author profile

Mateo

et al. 2008

Meas. Sci. Technol.

The observation of spectral components of the power dissipated by devices and circuits in integrated circuits (IC) by temperature measurements is limited by the bandwidth of either the temperature transducer or the intrinsic cut-off frequency provided by the thermal coupling inside the chip. In this paper, we use a heterodyne method to observe the high-frequency behavior of circuits and devices by means of low-frequency lock-in temperature measurements. As experimental results, two applications of the technique are presented: detection of hot spots in ICs activated by high-frequency electrical signals and the observation of the frequency response of an integrated resistor through temperature measurements. The heterodyne method has been used in this paper with four different measurement techniques: embedded differential BiCMOS temperature sensor, laser reflectometer, laser interferometer and internal IR laser deflection meter.

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Differential Temperature Sensors Fully Compatible With a 0.35-$\mu$m CMOS Process

Mateo

IEEE Trans. Comp. Packag. Technol.

2007

Electrothermal Design Procedure to Observe RF Circuit Power and Linearity Characteristics With a Homodyne Differential Temperature Sensor

Onabajo

IEEE Trans. Circuits Syst. I

et al. 2011

The focus in this paper is on the extraction of RF circuit performance characteristics from the dc output of an on-chip temperature sensor. Any RF input signal can be applied to excite the circuit under examination because only dissipated power levels are measured, which makes this approach attractive for online thermal monitoring and built-in test scenarios. A fully differential sensor topology is introduced that has been specifically designed for the proposed method by constructing it with a wide dynamic range, programmable sensitivity to dc, and RF power dissipation, as well as compatibility with CMOS technology. This paper also presents an outline of a procedure to model the local electrothermal coupling between heat sources and the sensor, which is used to define the temperature sensor's specifications as well as to predict the thermal signature of the circuit under test.A prototype chip with an RF amplifier and temperature sensor was fabricated in a conventional 0.18-m CMOS technology. The proposed concepts were validated by correlating RF measurements at 1 GHz with the measured dc voltage output of the on-chip sensor and the simulation results, demonstrating that the RF power dissipation can be monitored and the 1-dB compression point can be estimated with less than 1-dB error. The sensor circuitry occupies a die area of 0.012 mm , which can be shared when several on-chip locations are observed by placement of multiple temperature-sensing parasitic bipolar devices.Index Terms-CMOS temperature sensor, differential temperature sensing, electrothermal coupling, electrothermal IC design, homodyne measurement method, low-noise amplifier (LNA), on-chip temperature gradient measurement, radio frequency (RF) built-in test (BIT), radio frequency (RF) power detector.

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Electrical characterization of analogue and RF integrated circuits by thermal measurements

Mateo

Microelectronics Journal

2007