Abstract: The present disclosure is directed to a master-slave flip-flop memory circuit having a partial pass gate transistor at the input of the master latch. The partial pass gate transistor includes a pull-up clock enabled transistor for selectively coupling a high output of a test switch to the input of the master latch. The input of the master latch is also directly coupled to a low output of the test switch around the partial pass gate. In addition, a revised circuit layout is provided in which the master latch has three inverters. A first inverter is coupled to the input of the master latch. Second and third inverters are coupled to an output of the first inverter, with the second inverter having an output coupled to the input of the first inverter, and the third inverter having an output coupled to an output of the master latch. The first and second inverters are clock enabled, and the third inverter is reset enabled.

Abstract: A flip flop includes a data input, a clock input, a test chain input, a test chain output, a monitoring circuit, and an alert transmission circuit. The monitoring circuit is adapted to generate an alert if the time between arrival of a data bit and a clock edge is less than a threshold. The alert transmission circuit is adapted to apply during a monitoring phase an alert level to the test chain output in the event of an alert generated by the monitoring circuit, and to apply the alert level to the test chain output when an alert level is received at the test chain input.

Abstract: The present disclosure is directed to a master-slave flip-flop memory circuit having a partial pass gate transistor at the input of the master latch. The partial pass gate transistor includes a pull-up clock enabled transistor for selectively coupling a high output of a test switch to the input of the master latch. The input of the master latch is also directly coupled to a low output of the test switch around the partial pass gate. In addition, a revised circuit layout is provided in which the master latch has three inverters. A first inverter is coupled to the input of the master latch. Second and third inverters are coupled to an output of the first inverter, with the second inverter having an output coupled to the input of the first inverter, and the third inverter having an output coupled to an output of the master latch. The first and second inverters are clock enabled, and the third inverter is reset enabled.

Abstract: The present disclosure is directed to a master-slave flip-flop memory circuit having a partial pass gate transistor at the input of the master latch. The partial pass gate transistor includes a pull-up clock enabled transistor for selectively coupling a high output of a test switch to the input of the master latch. The input of the master latch is also directly coupled to a low output of the test switch around the partial pass gate. In addition, a revised circuit layout is provided in which the master latch has three inverters. A first inverter is coupled to the input of the master latch. Second and third inverters are coupled to an output of the first inverter, with the second inverter having an output coupled to the input of the first inverter, and the third inverter having an output coupled to an output of the master latch. The first and second inverters are clock enabled, and the third inverter is reset enabled.

Abstract: The synchronous retention flip-flop circuit comprises a first circuit module suitable for being powered by an interruptible power source and a second circuit module suitable for being powered by a permanent power source. The first circuit module includes first and second latch stages, which are configured to store at least one datum while said interruptible power source is supplying power, transmitting means suitable for being controlled by a second control signal and configured to deliver said at least one datum to the second circuit module before an interruption of said interruptible power source, the second circuit module being configured to preserve said at least one datum during said interruption, and restoring means suitable for being controlled by a first control signal and configured to restore said at least one datum at the end of said interruption. Only the second control signal remains active during interruption of the interruptible power source.

Abstract: A flip flop includes a data input, a clock input, a test chain input, a test chain output, a monitoring circuit, and an alert transmission circuit. The monitoring circuit is adapted to generate an alert if the time between arrival of a data bit and a clock edge is less than a threshold. The alert transmission circuit is adapted to apply during a monitoring phase an alert level to the test chain output in the event of an alert generated by the monitoring circuit, and to apply the alert level to the test chain output when an alert level is received at the test chain input.

Abstract: A synchronous retention flip-flop circuit includes a first circuit module powered by an interruptible power source and a second circuit module powered by a permanent power source. The first circuit module includes a first latch circuit and a second latch circuit which are configured to store at least one datum while the interruptible power source is supplying power. A transmission circuit operates to deliver the at least one datum to the second circuit module before an interruption of the interruptible power source. The second circuit module preserves the at least one datum during the interruption. Following an end of the interruption, a restoring circuit transfers the at least one datum from the second circuit module to the first circuit module via a single one of the first and second latch circuits.

Abstract: The synchronous retention flip-flop circuit comprises a first circuit module suitable for being powered by an interruptible power source and a second circuit module suitable for being powered by a permanent power source. The first circuit module includes first and second latch stages, which are configured to store at least one datum while said interruptible power source is supplying power, transmitting means suitable for being controlled by a second control signal and configured to deliver said at least one datum to the second circuit module before an interruption of said interruptible power source, the second circuit module being configured to preserve said at least one datum during said interruption, and restoring means suitable for being controlled by a first control signal and configured to restore said at least one datum at the end of said interruption. Only the second control signal remains active during interruption of the interruptible power source.

Abstract: A synchronous retention flip-flop circuit includes a first circuit module powered by an interruptible power source and a second circuit module powered by a permanent power source. The first circuit module includes a first latch circuit and a second latch circuit which are configured to store at least one datum while the interruptible power source is supplying power. A transmission circuit operates to deliver the at least one datum to the second circuit module before an interruption of the interruptible power source. The second circuit module preserves the at least one datum during the interruption. Following an end of the interruption, a restoring circuit transfers the at least one datum from the second circuit module to the first circuit module via a single one of the first and second latch circuits.

Abstract: An electronic device includes a pulsed latch circuit configured to latch a data input signal to an output based upon receipt of a pulse signal. A pulse generation circuit is configured to compare the data input signal and an output signal at the output of the pulsed latch circuit, and to generate the pulse signal based upon a mismatch therebetween in response to a clock signal.