Integrated circuits (12) are manufactured by printing an array of circuit elements CE each containing an integrated circuit and associated testing circuitry (14). A plurality of integrated circuits within the array are tested in parallel to generate a corresponding plurality of individual test result signals. These individual test result signals are combined to form a combined test result signal indicating whether any of the plurality of integrated circuits tested in parallel operated incorrectly during their testing. If the combined test result signal indicates any faulty integrated circuits, then the entire plurality of integrated circuits (e.g. an entire row or column) may be discarded. The array of tested integrated circuits are then separated into discrete integrated circuits and are also separated from their testing circuit. Contacts (16, 18, 20) providing power signals, clock signals, and the reading of the combined test result signals are located at the periphery of a substrate sheet onto which the array of circuit elements are printed.

Symbolic backend for execution of quantum programs is provided. A parser receives an input qasm and parses it as a circuit graph. A layering component segments the circuit graph into multiple layers. An evaluation engine reads respective layers, translates the respective layers into a mathematic expression over qubits, and performs a simplification of the input qasm. A checker determines whether the input qasm and the simplified qasm are equivalent.

A control system is disclosed. The control system includes an input module (IM) configured to be detachably coupled to a connection plane, an output module (OM) configured to be detachably coupled to the connection plane, and a logic module (LM) configured to be detachably coupled to the connection plane. The IM, OM, and LM are devoid of any programmable devices in any electronic path from any input port to any output port of the IM, OM, and LM.

A chain of flip-flops is tested by passing a reference signal through the chain. The reference signal is generated from a test pattern that is cyclically fed back at the cadence of a clock signal. The reference signal propagates through the chain of flip-flops at the cadence of the clock signal to output a test signal. A comparison is carried out at the cadence of the clock signal of the test signal and the reference signal, where the reference signal is delayed by a delay time taking into account the number of flip-flops in the chain and the length of the test pattern. An output signal is produced, at the cadence of the clock signal, as a result of the comparison.

According to a first aspect of the present invention, there is provided a method, a computer system and a computer program product. The method, computer system and computer program product including measuring an initial state of a set of SRAM bits on the wafer, identifying a first set of signature SRAM bits on the wafer, of the set of SRAM bits on the wafer, where the first set of SRAM bits comprise a consistent initial state greater than a first threshold percentage of times, measuring physically dimensions of features of the first set of SRAM bits on the wafer; and identifying a set of signature SRAM bits of the first set of SRAM bits on the wafer, wherein the set of signature SRAM bits comprise physical dimensions of features which correlate to the initial state of each correlated SRAM bit.

In one embodiment, a multiple input signature register (MISR) shadow works with a MISR to compress test responses of a layout partition in a functional region of an integrated circuit. In operation, for each test pattern in a test pattern split, the MISR generates a MISR signature based on the responses of the layout partition. As the test patterns in the test pattern split execute, the MISR shadow accumulates the MISR signatures and stores the result as MISR shadow data. After the final test pattern included in the test pattern split executes, the MISR shadow combines the bits in the MISR shadow data to form a single bit MISR shadow status that indicates whether the layout partition, and therefore the functional region, responds properly to the test pattern split. By efficiently summarizing the test responses, the MISR shadow optimizes the resources required to identify defective functional regions.

Techniques relate to an interactive logic diagnostic process. A diagnostic iteration loop is performed. When a critical failure does not have the diagnostic resolution that meets a predefined diagnostic resolution, potential faults related to the critical failure are isolated. When the critical failure has a diagnostic resolution that meets the predefined diagnostic resolution, the diagnostic iteration loop ends. Path focused fault test patterns are applied to the device under test in order to generate updated results of the path focused fault test patterns, such that the diagnostic resolution has been increased because a number of the potential faults related to the critical failure has decreased, and/or a size of a physical area of the potential faults related to the critical failure has decreased. The diagnostic iteration loop is returned to.

Aspects of the invention provide for reducing BIST test time for a memory of an IC chip. In one embodiment, a BIST architecture for reducing BIST test time of a memory for an integrated circuit (IC) chip, the architecture comprising: a pair of latches for receiving bursts of data from a memory; a first compression stage for receiving a burst of data and compressing the burst of data into a plurality of latches; a second compression stage for comparing the compressed bursts of data with expected data; and a logic gate for determining whether there is a fail in the burst of data.

Disclosed herein is a method of detecting an arc generated in a semiconductor device. The method may comprise: performing a processing process for a substrate processing and collecting data according to the processing process; separating the collected data by setting sections; obtaining an average value and a standard deviation of the data separated for each section; and setting an upper limit and a lower limit for detecting the arc using the average value and the standard deviation.

Described is an apparatus which comprises: a state detector which is operable to detect logic states of zero and one in response to a clock edge; and an error detector coupled to the state detector, wherein the error detector is to detect an error in the detected logic states.