Christian Landrault

A test vector inhibiting technique for low energy BIST design

During self-test, the switching activity of the circuit under test is significantly increased compared to normal operation and leads to an increased power consumption which often exceeds specified limits. In the first part of this paper, we propose a test vector inhibiting technique which tackles the increased activity during test operation. Next, a mixed solution based on a reseeding scheme and the vector inhibiting technique is proposed to deal with hard-to-test circuits that contain pseudo-random resistant faults. From a general point of view, the goal of these techniques is to minimize the total energy consumption during test and to allow the test at system speed in order to achieve high fault coverage. The effectiveness of the proposed low energy BIST scheme has been validated on a set of benchmarks with respect to hardware overhead and power savings.

A gated clock scheme for low power scan testing of logic ICs or embedded cores

Test power is now a big concern in large system-on-chip designs. In this paper, we present a novel approach for minimizing power consumption during scan testing of integrated circuits or embedded cores. The proposed low power technique is based on a gated clock scheme for the scan path and the clock tree feeding the scan path. The idea is to reduce the clock rate on scan cells during shift operations without increasing the test time. Numerous advantages can be found in applying such a technique.

A modified clock scheme for a low power BIST test pattern generator

In this paper, we present a new low power test-per-clock BIST test pattern generator that provides test vectors which can reduce the switching activity during test operation. The proposed low power/energy BIST technique is based on a modified clock scheme for the TPG and the clock tree feeding the TPG. Numerous advantages can be found in applying such a technique during BIST.

Power driven chaining of flip-flops in scan architectures

Power consumption during scan testing is becoming a primary concern. In this paper, we present a novel approach for scan cell ordering which significantly reduces the power consumed during scan testing. The proposed approach is based on the use of a two-step heuristic procedure that can be exploited by any chip layout program during scan flip-flops placement and routing. The proposed approach works for any conventional scan design and offers numerous advantages compared with existing low power scan techniques. Reductions of average and peak power consumption during scan testing are up to 58% and 24% respectively for experimented ISCAS benchmark circuits.

Efficient scan chain design for power minimization during scan testing under routing constraint

Scan-based architectures, though widely used in modern designs, are expensive in power consumption. In this paper, we present a new technique that allows to design power-optimized scan chains under a given routing constraint. The proposed technique is a three-phase process based on clustering and reordering of scan cells in the design. It allows to reduce average power consumption during scan testing. Owing to this technique, short scan connections in scan chains are guaranteed and congestion problems in the design are avoided.

On calculating efficient LFSR seeds for built-in self test

Linear Feedback Shift Registers (LFSRs) are commonly used as pseudo-random test pattern generators (TPGs) in BIST schemes. This paper presents a fast simulation-based method to compute an efficient seed (initial state) of a given primitive polynomial LFSR TPG. The size of the LFSR, the primitive feedback polynomial and the length of the generated test sequence are a priori known. The method uses a deterministic test cube compression technique and produces a one-seed LFSR test sequence of a predefined test length that achieves high fault coverage. This technique can be applied either in pseudo-random testing for BISTed circuits containing few random resistant faults, or in pseudo-deterministic BIST where it allows the hardware generator overhead area to be reduced. Compared with existing methods, the proposed technique is able to deal with combinational circuits of great size and with a lot of primary inputs. Experimental results demonstrate the effectiveness of our method.

Circuit partitioning for low power BIST design with minimized peak power consumption

In this paper, we propose a novel low power/energy built-in self test (BIST) strategy based on circuit partitioning. The goal of the proposed strategy is to minimize the average power, the peak power and the energy consumption during pseudo-random testing without modifying the fault coverage. The strategy consists in partitioning the original circuit into two structural subcircuits so that each subcircuit can be successively tested through two different BIST sessions. In partitioning the circuit and planning the test session, the switching activity in a time interval (i.e. the average power) as well as the peak power consumption are minimized. Moreover, the total energy consumption during BIST is also reduced since the test length required to test the two subcircuits is roughly the same as the test length for the original circuit. Results on ISCAS circuits show that average power reduction of up to 72%, peak power reduction of up to 53%, and energy reduction of up to 84% can be achieved.

An optimized BIST test pattern generator for delay testing

As delay testing using external testers requires expensive equipment, built-in self-test (BIST) is an alternative technique that can significantly reduce the test cost. In this paper, a BIST test pattern generator (TPG) design for the detection of delay faults is proposed. This TPG design produces test sequences having exactly the same robust delay fault coverage as single input change (SIC) test sequences obtained with the most efficient TPGs proposed before in the literature, but with a reduced test length and less area overhead. This reduction of the test length and area overhead is obtained by determining compatible inputs of the circuit under test (CUT), i.e. inputs that can be switch simultaneously without altering the robust test coverage.

Low power BIST by filtering non-detecting vectors

In this paper, two techniques to reduce the energy and the average power consumption of the system are proposed. They are based on the fact that as the test progresses, the detection efficiency of the pseudo-random vectors decreases very quickly. Many of the pseudo-random vectors will not detect faults in spite of consuming a significant amount of energy from the power supply. In order to prevent this energy consumption, a filtering of the non-detecting vectors and a reseeding strategy are proposed.These techniques are evaluated on the set of ISCAS-85 benchmark circuits. Extensive simulations have been made using the SAIL energy simulator showing that, in large circuits, the energy consumption and the average power savings reach 90.0% with a mean value of 74.2% with the filtering technique, and 97.2% with an average value of 90.9% with the reseeding strategy.

A test vector ordering technique for switching activity reduction during test operation

This paper considers the problem of testing VLSI integrated circuits without exceeding their power ratings during test. The proposed approach is based on the reordering of test vectors of a given test sequence to minimize the average and peak power dissipation during test operation. For this purpose, the proposed technique reduces the internal switching activity by lowering the transition density at circuit inputs. The technique considers combinational or full scan sequential circuits and do not modify the initial fault coverage. Results of experiments show reductions of the switching activity ranging from 11% to 66% during external test application.