Abstract: A system and method enable strengthening of flip-Flops (FFs) in an integrated circuit (IC) for the purpose of reducing power consumption. This is achieved by using stability condition (STC) and observability don't-care (ODC) techniques. Strengthening enable is defined as ensuring that a FF later in the fan-out is enabled only when a FF earlier in the fan-out is driving a signal to that later FF. In an embodiment the fan-in of a FF is traversed and the STC or ODC is determined for the FF. Dependent on the determination a STC controller or an ODC controller is added to control the FF's enable signal. In an embodiment the power savings is checked and a controller is added only if there is a reduction in overall power consumption resulting from the addition of the controller.

Abstract: A system and method enable strengthening of flip-Flops (FFs) in an integrated circuit (IC) for the purpose of reducing power consumption. This is achieved by using stability condition (STC) and observability don't-care (ODC) techniques. Strengthening enable is defined as ensuring that a FF later in the fan-out is enabled only when a FF earlier in the fan-out is driving a signal to that later FF. In an embodiment the fan-in of a FF is traversed and the STC or ODC is determined for the FF. Dependent on the determination a STC controller or an ODC controller is added to control the FF's enable signal. In an embodiment the power savings is checked and a controller is added only if there is a reduction in overall power consumption resulting from the addition of the controller.

Abstract: The circuit design process requires ways to reduce the power consumption of large integrated circuits and system-on-chip designs. This is typically done by introducing a process of clock gating thereby enabling or disabling flip-flops associated with specific functional blocks within the circuit. However, such changes in the circuit require synthesis and verification to ensure correctness of design and operation as sequential clock gating changes the state function dynamically. It is therefore necessary to define synthesis methods adapted to such dynamic changes in the design. According to an embodiment a sequential clock gating method uses an exclusive-OR technique to overcome the deficiencies of the prior art methods.

Abstract: The circuit design process requires ways to reduce the power consumption of large integrated circuits and system-on-chip designs. This is typically done by introducing a process of clock gating thereby enabling or disabling flip-flops associated with specific functional blocks within the circuit. However, such changes in the circuit require synthesis and verification to ensure correctness of design and operation as sequential clock gating changes the state function dynamically. It is therefore necessary to define synthesis methods adapted to such dynamic changes in the design. According to an embodiment a sequential clock gating method uses an exclusive-OR technique to overcome the deficiencies of the prior art methods.

Abstract: A system and method enable strengthening of flip-Flops (FFs) in an integrated circuit (IC) for the purpose of reducing power consumption. This is achieved by using stability condition (STC) and observability don't-care (ODC) techniques. Strengthening enable is defined as ensuring that a FF later in the fan-out is enabled only when a FF earlier in the fan-out is driving a signal to that later FF. In an embodiment the fan-in of a FF is traversed and the STC or ODC is determined for the FF. Dependent on the determination a STC controller or an ODC controller is added to control the FF's enable signal. In an embodiment the power savings is checked and a controller is added only if there is a reduction in overall power consumption resulting from the addition of the controller.

Abstract: As part of the design process it is required to design circuits in order to reduce their power consumption. This is typically done by enabling or disabling flip-flops (FFs), however, such change in the circuit requires certain verification. As sequential clock gating changes the state function it is necessary to perform a sequential equivalence checking (SEC) verification. Applying a full SEC may be runtime consuming and is not scalable for large designs. Methods to reduce the problem of verifying sequential clock gating by reducing the sequential problem into much smaller problem that can be easily solved is therefore shown.

Abstract: As part of the design process it is required to design circuits in order to reduce their power consumption. This is typically done by enabling or disabling flip-flops (FFs), however, such change in the circuit requires certain verification. As sequential clock gating changes the state function it is necessary to perform a sequential equivalence checking (SEC) verification. Applying a full SEC may be runtime consuming and is not scalable for large designs. Methods to reduce the problem of verifying sequential clock gating by reducing the sequential problem into much smaller problem that can be easily solved is therefore shown.

Abstract: A technique and apparatus for reducing the complexity of optimizing the performance of a designed semiconductor circuit is disclosed. This technique of path compaction is used to reduce the time taken for optimization. The path compaction tool is used in design optimization to reduce the optimizer execution time. Compaction helps readability, usability and reduces synthesis and static timing analyzer (STA) runtime. The aim of path compaction is to reduce the number of constraints the optimizer has to go through during the optimization process. Path compaction has three dimensions. The first is to reduce number of “-through” elements in the constraint, thereby reducing the complexity of constraints developed The second is to combine the paths to reduce the number of constraints. The third is to combine the constraints to reduce the number of constraints to be checked and optimized. Path compaction is used when generating timing exception using timing exception tools.

Abstract: A technique and apparatus for reducing the complexity of optimizing the performance of a designed semiconductor circuit is disclosed. This technique of path compaction is used to reduce the time taken for optimization. The path compaction tool is used in design optimization to reduce the optimizer execution time. Compaction helps readability, usability and reduces synthesis and static timing analyzer (STA) runtime. The aim of path compaction is to reduce the number of constraints the optimizer has to go through during the optimization process. Path compaction has three dimensions. The first is to reduce number of “-through” elements in the constraint, thereby reducing the complexity of constraints developed The second is to combine the paths to reduce the number of constraints. The third is to combine the constraints to reduce the number of constraints to be checked and optimized. Path compaction is used when generating timing exception using timing exception tools.

Abstract: A method and system for timing exception verification in integrated circuit (IC) designs included verification of functional false paths as well as multi-cycle paths (MCPs). A false path or a MCP is modeled to a satisfiability formula and the formula is validated using a Boolean satisfiability solver. Time required for timing exception verification can be significantly reduced.

Abstract: A method and system for timing exception verification in integrated circuit (IC) designs included verification of functional false paths as well as multi-cycle paths (MCPs). A false path or a MCP is modeled to a satisfiability formula and the formula is validated using a Boolean satisfiability solver. Time required for timing exception verification can be significantly reduced.

Abstract: A method for generating timing exceptions for integrated circuit (IC) designs is disclosed. The method includes synthesizing an input RTL description into a gate-level netlist mapped to a technology library; detecting timing critical paths in the netlist; and determining for each detected timing critical path whether it induces timing exceptions. The timing exceptions generated by the disclosed method include, but are not limited to, multi-cycle paths, clock domain crossing false paths, asynchronous false paths, functional false paths, combinational false paths, sequential false paths, timing false paths, and the like.