Abstract: An upconverting circuit is disclosed. The upconverting circuit includes a polyphase component generator that provides Np polyphase components at each input polyphase cycle, wherein Np>2 on each input polyphase cycle defined by a clock. A memory stores the polyphase components from at least one polyphase cycle prior to the current polyphase cycle. A plurality of filters process the polyphase components stored in the memory. Each filter processes a plurality of the polyphase components to generate a filtered polyphase component corresponding to that filter. A multiplexer outputs the filtered polyphase components in a predetermined order to generate a filtered output signal. In one embodiment, each filter utilizes the same functional relationship to generate the filtered polyphase components. In another embodiment, the memory is a shift register. The filters can be of arbitrary complexity.

Abstract: A method for calibrating time interleaved samplers comprising applying a calibration signal to a time-interleaved sampling device, wherein the signal is coherent with at least one sample clock on the device and is periodic and has a predetermined spectral content and frequency, sampling, by said time-interleaved sampling device, the calibration signal at a plurality of phases to form samples, averaging the formed samples, and calculating the phase error of each sample based on the average calibration signal sample.

Abstract: The method defines an input state vector that achieves low power consumption when applied to the circuit inputs of a digital circuit in an idle state. The digital circuit includes one or more circuit elements of respective circuit element types. In the method, idle power values including idle power values for each circuit element type. The idle power values for each circuit element type correspond to different states of the inputs of a circuit element of the circuit element type. Additionally the idle power values are used to determine, for each circuit element, states of the inputs of the circuit element that would set the circuit element to a lowest-allowable idle power state when the digital circuit is in the idle state. The states determined for those of the inputs that constitute the circuit inputs define the input state vector. The states are also determined accounting for the logic constraints of the digital circuit.

Abstract: The method defines an input state vector that achieves low power consumption when applied to the circuit inputs of a digital circuit in an idle state. In the method, independent determinations are performed. Each determination defines a respective set of the input states of the input state vector. Any conflict the definitions of any one or more of the input states is resolved in favor of the definition of the one or more of the input states that achieves the lowest idle power consumption when the input state vector incorporating the one or more of the input states in accordance with the definition is applied to the circuit inputs of the digital circuit in the idle state.

Abstract: A clock gating circuit reduces the power dissipation in a digital circuit including at least one functional block by gating the clock signal at an input to a clock tree feeding the functional block. The clock gating circuit includes a logic gate that receives a clock signal and a clock disable signal generated by the functional block, and gates the clock signal at the input to the clock tree feeding the functional block. Further, a global signal generator is provided to transmit a global signal to each of the functional blocks to prevent the generation of clock disable signals, when necessary, such as during testing of chips.

Abstract: The method defines an input state vector that achieves low power consumption when applied to the circuit inputs of a digital circuit in an idle state. In the method, independent determinations are performed. Each determination defines a respective set of the input states of the input state vector. Any conflict the definitions of any one or more of the input states is resolved in favor of the definition of the one or more of the input states that achieves the lowest idle power consumption when the input state vector incorporating the one or more of the input states in accordance with the definition is applied to the circuit inputs of the digital circuit in the idle state.

Abstract: The method defines an input state vector that achieves low power consumption when applied to the circuit inputs of a digital circuit in an idle state. The digital circuit includes one or more circuit elements of respective circuit element types. In the method, idle power values including idle power values for each circuit element type. The idle power values for each circuit element type correspond to different states of the inputs of a circuit element of the circuit element type. Additionally the idle power values are used to determine, for each circuit element, states of the inputs of the circuit element that would set the circuit element to a lowest-allowable idle power state when the digital circuit is in the idle state. The states determined for those of the inputs that constitute the circuit inputs define the input state vector. The states are also determined accounting for the logic constraints of the digital circuit.

Abstract: A clock gating circuit reduces the power dissipation in a digital circuit including at least one functional block by gating the clock signal at an input to a clock tree feeding the functional block. The clock gating circuit includes a logic gate that receives a clock signal and a clock disable signal generated by the functional block, and gates the clock signal at the input to the clock tree feeding the functional block. Further, a global signal generator is provided to transmit a global signal to each of the functional blocks to prevent the generation of clock disable signals, when necessary, such as during testing of chips.

Abstract: A circuit design system that obtains low power circuit design through judicious module selection. The circuit design system implements methods that enable advantageous design tradeoffs between low power behavior and a set of design constraints during module selection. The circuit design system selects unsigned modules which consume less power than signed modules where permitted in view of a desired response of a circuit and where advantageous for low power behavior while not violating the design constraints.

Abstract: A circuit design system that obtains low power circuit design through judicious module selection. The circuit design system implements methods that enable advantageous design tradeoffs between low power behavior and a set of design constraints during module selection. The circuit design system selects unsigned modules which consume less power than signed modules where permitted in view of a desired response of a circuit and where advantageous for low power behavior while not violating the design constraints.