Abstract: Crossbar circuitry has data input and output paths, and at each intersection between a data input and output path, a crossbar cell is provided. A transmission circuit is responsive to a stored routing value to couple a data input path to a selected data output path. Pre-selection circuitry cooperates with the pre-selection circuits of other crossbar cells on the same data output path to use the bit lines of the data output path to compare quality-of-service values associated with multiple asserted transmission requests and to determine a subset thereof which have a highest value of the quality-of-service values. Arbitration circuitry implements a predetermined priority scheme to choose from that subset of requests and to cause the configuration storage circuit of only one crossbar cell associated with the same data output path to have its routing value programmed to the first value, thereby resolving conflict between multiple asserted transmission requests.

Abstract: Crossbar circuitry, and a method of operation of such crossbar circuitry, are provided. The crossbar circuitry has an array of data input paths and data output paths where the data output paths are transverse to the data input paths. At each intersection between a data input path and a data output path, a crossbar cell is provided that comprises a configuration storage circuit programmable to store a routing value, a transmission circuit, and an arbitration circuit. In a transmission mode of operation, the transmission circuit is responsive to the routing value being a first value, indicating that the data input path should be coupled to the data output path, to detect the data input along the data input path, and to output an indication of that data on the data output path at the associated intersection.

Abstract: An integrated circuit 2 includes logic circuitry 10 and sequential storage elements 8. Both the logic circuit 10 and sequential storage elements 8 can be subject to particle strikes giving rise to single event upset errors. These single event upset errors can be detected by detecting a transition in the stored value stored by the sequential storage elements 8 occurring outside of a valid transition period associated with that sequential storage element 8.

Abstract: An integrated circuit includes a plurality of processing stages each including processing logic, a non-delayed signal-capture element, a delayed signal-capture element and a comparator. The non-delayed signal-capture element captures an output from the processing logic at a non-delayed capture time. At a later delayed capture time, the delayed signal-capture element also captures a value from the processing logic. An error detection circuit and error correction circuit detect and correct random errors in the delayed value and supplies an error-checked delayed value to the comparator. The comparator compares the error-checked delayed value and the non-delayed value and if they are not equal this indicates that the non-delayed value was captured too soon and should be replaced by the error-checked delayed value.

Abstract: Crossbar circuitry has data input and output paths, and at each intersection between a data input and output path, a crossbar cell is provided. A transmission circuit is responsive to a stored routing value to couple a data input path to a selected data output path. Pre-selection circuitry cooperates with the pre-selection circuits of other crossbar cells on the same data output path to use the bit lines of the data output path to compare quality-of-service values associated with multiple asserted transmission requests and to determine a subset thereof which have a highest value of the quality-of-service values. Arbitration circuitry implements a predetermined priority scheme to choose from that subset of requests and to cause the configuration storage circuit of only one crossbar cell associated with the same data output path to have its routing value programmed to the first value, thereby resolving conflict between multiple asserted transmission requests.

Abstract: Crossbar circuitry, and a method of operation of such crossbar circuitry, are provided. The crossbar circuitry has an array of data input paths and data output paths where the data output paths are transverse to the data input paths. At each intersection between a data input path and a data output path, a crossbar cell is provided that comprises a storage circuit programmable to store a routing value, and a transmission circuit. In a transmission mode of operation the transmission circuit is responsive to the routing value indicating that the data input path should be coupled to the data output path to detect the data input along the data input path, and to output an indication of that data on the data output path at the associated intersection. Control circuitry is used to issue control signals to the crossbar cells, and during a configuration mode of operation the control circuitry re-utilizes at least one of the data output paths to program the storage circuitry of one or more of the crossbar cells.

Abstract: A memory cell structure for a memory device includes a read transistor having a floating gate node, a tunnelling capacitor, and a coupling capacitor stack. The tunnelling capacitor is connected to the floating gate node and has a first programming terminal, and the coupling capacitor stack is connected to the floating gate node and has a second programming terminal. The coupling capacitor stack includes at least two coupling capacitors arranged in series between the floating gate node and the second programming terminal, with the coupling capacitor stack having a larger capacitance than the tunnelling capacitor. Such a memory cell structure is efficient in terms of area, and can be manufactured using standard CMOS logic manufacturing processes, thereby avoiding some of the complexities involved in the production of conventional EEPROM and Flash memory devices.

Abstract: An integrated circuit is provided with domino logic including a speculative node and a checker node. Precharged circuitry precharges both the speculative node and the checker node. Logic circuitry provides a discharge path for the speculative node and the checker node in dependence upon input signal values. Evaluation control circuitry first couples the speculative node to the logic circuitry and then subsequently couples the checker node to the logic circuitry such that these can be discharged if the input signals to the logic circuitry have appropriate values. Error detection circuitry detects an error when the speculative node and the checker node are not one of both discharged or both undischarged.

Abstract: An integrated circuit includes a plurality of processing stages each including processing logic 1014, a non-delayed signal-capture element 1016, a delayed signal-capture element 1018 and a comparator 1024. The non-delayed signal-capture element 1016 captures an output from the processing logic 1014 at a non-delayed capture time. At a later delayed capture time, the delayed signal-capture element 1018 also captures a value from the processing logic 1014. An error detection circuit 1026 and error correction circuit 1028 detect and correct random errors in the delayed value and supplies an error-checked delayed value to the comparator 1024. The comparator 1024 compares the error-checked delayed value and the non-delayed value and if they are not equal this indicates that the non-delayed value was captured too soon and should be replaced by the error-checked delayed value.

Abstract: An integrated circuit is provided with domino logic including a speculative node and a checker node. Precharged circuitry precharges both the speculative node and the checker node. Logic circuitry provides a discharge path for the speculative node and the checker node in dependence upon input signal values. Evaluation control circuitry first couples the speculative node to the logic circuitry and then subsequently couples the checker node to the logic circuitry such that these can be discharged if the input signals to the logic circuitry have appropriate values. Error detection circuitry detects an error when the speculative node and the checker node are not one of both discharged or both undischarged.

Abstract: An integrated circuit is provided with domino logic including a speculative node and a checker node. Precharged circuitry precharges both the speculative node and the checker node. Logic circuitry provides a discharge path for the speculative node and the checker node in dependence upon input signal values. Evaluation control circuitry first couples the speculative node to the logic circuitry and then subsequently couples the checker node to the logic circuitry such that these can be discharged if the input signals to the logic circuitry have appropriate values. Error detection circuitry detects an error when the speculative node and the checker node are not one of both discharged or both undischarged.

Abstract: A data processing circuitry for processing data is disclosed.

Abstract: Crossbar circuitry has an array of data input and output paths where the data output paths are transverse to the data input paths. At each intersection between a data input path and a data output path, a crossbar cell is provided which includes a configuration storage circuit programmable to store a routing value, a transmission circuit, and an arbitration circuit. In a transmission mode of operation, the transmission circuit is responsive to the routing value being a first value, indicating that the data input path should be coupled to the data output path, to detect the data input along the data input path, and to output an indication of that data on the data output path at the associated intersection. In an arbitration mode of operation, the arbitration circuitry is operable to selectively modify the voltage on said plurality of bit lines in order to apply an adaptive priority scheme.

Abstract: An integrated circuit includes a plurality of processing stages each including processing logic 1014, a non-delayed signal-capture element 1016, a delayed signal-capture element 1018 and a comparator 1024. The non-delayed signal-capture element 1016 captures an output from the processing logic 1014 at a non-delayed capture time. At a later delayed capture time, the delayed signal-capture element 1018 also captures a value from the processing logic 1014. An error detection circuit 1026 and error correction circuit 1028 detect and correct random errors in the delayed value and supplies an error-checked delayed value to the comparator 1024. The comparator 1024 compares the error-checked delayed value and the non-delayed value and if they are not equal this indicates that the non-delayed value was captured too soon and should be replaced by the error-checked delayed value.

Abstract: An integrated circuit includes one or more portions having error detection and error correction circuits and which is operated with operating parameters giving finite non-zero error rate as well as one or more portions formed and operated to provide a zero error rate.

Abstract: An integrated circuit includes a plurality of processing stages each including processing logic 1014, a non-delayed signal-capture element 1016, a delayed signal-capture element 1018 and a comparator 1024. The non-delayed signal-capture element 1016 captures an output from the processing logic 1014 at a non-delayed capture time. At a later delayed capture time, the delayed signal-capture element 1018 also captures a value from the processing logic 1014. An error detection circuit 1026 and error correction circuit 1028 detect and correct random errors in the delayed value and supplies an error-checked delayed value to the comparator 1024. The comparator 1024 compares the error-checked delayed value and the non-delayed value and if they are not equal this indicates that the non-delayed value was captured too soon and should be replaced by the error-checked delayed value.

Abstract: An isolation circuitry and method are provided for coupling between a power supply and processing circuitry in order to provide power to the processing circuitry whilst hiding a power consumption characteristic of that processing circuitry. The isolation circuitry comprises a plurality of sub-circuits, with each sub-circuit comprising a capacitor, a first switch configured to provide a first connection between the capacitor and the power supply, a second switch configured to provide a second connection between the capacitor and the processing circuitry, and a third switch configured to provide a third connection across the capacitor to partially discharge the capacitor. Control circuitry controls the plurality of sub-circuits, such that within each sub-circuit the first switch, second switch and third switch are placed in an active state in a repeating sequence.

Abstract: A memory cell 36 within an integrated circuit memory is provided with an access controller 32 coupled to a first pass gate 38 and a second pass gate 40. During a write access to the memory cell 38 both the first pass gate 38 and the second pass gate 40 are opened. During a read access, the first pass gate 38 is opened and the second pass gate 40 is closed. This asymmetry in the read and write operations permits an asymmetry in the gates forming the memory cell 36 thereby permitting changes to increase both read robustness and write robustness. The asymmetry in the design parameters of different gates can take the form of varying the gate length, the gate width and the threshold voltage so as to vary the conductance of different gates to suit their individual role within the memory cell 36 which is operating in the asymmetric manner provided by the separate word line signals driving read operations and write operations.

Abstract: An integrated circuit (100) is provided with power regulating circuitry (104) serving to actively regulate the voltage difference between a first power supply rail Vdd and a second power rail Vss being used to supply electrical power to processing circuitry (102). A voltage regulating capacitor Ca has one terminal connected to the first power rail Vdd and a second terminal selectively connected to either the second power rail Vss or a third power rail Vdda. Should a voltage undershoot be detected by voltage sensing circuitry 106, then the capacitor Ca is connected to the third power rail Vdda so as to dump at least part of charge Ca, Vdda in capacitor Ca onto the first power rail Vdd and resist the voltage drop. During normal operation, charge is accumulated into the capacitor Ca. An additional load device T2 is provided to lower the voltage difference should an overshoot be detected.

Abstract: An integrated circuit 2 is provided with domino logic including a speculative node 22 and a checker node 24. Precharged circuitry 36 precharges both the speculative node and the checker node. Logic circuitry 26 provides a discharge path for the speculative node and the checker node in dependence upon input signal values. Evaluation control circuitry 28, 30 first couples the speculative node to the logic circuitry and then subsequently couples the checker node to the logic circuitry such that these can be discharged if the input signals to the logic circuitry 26 have appropriate values. Error detection circuitry 32 detects an error when the speculative node and the checker node are not one of both discharged or both undischarged.