Abstract: A method and system is described for managing the development of software source code, and in addition, collecting useful metrics about the development process. A first source code is provided in a desired state. The desired state may be the requirement that the source code can be built or the desired state may be the requirement that the source code can be built and pass one or more tests. A second source code is then received. The second source may be a modified copy of the source code. It is then determined whether the second source code is in the desired state, and the first source code is updated using the second source code in response to the second source code being in the desired state. Metrics that may be collected include: the name of a task, time to complete the task, line of code involved, etc.

Abstract: A CMOS gain stage includes biasing circuitry configured to insure saturation of a subsequent stage without a source follower circuit. The CMOS gain stage is optionally powered by a supply voltage that is greater than a permitted supply voltage for a processes technology that is used to fabricate the CMOS gain stage. In order to protect CMOS devices within the CMOS gain stage, optional drain-to-bulk junction punch-through protection circuitry is disclosed. A variety of optional features can be implemented alone and/or in various combinations of one another. Optional features include process-voltage-temperature (“PVT”) variation protection circuitry, which renders a gain relatively independent of process, voltage, and/or temperature variations. Optional features further include bandwidth enhancement circuitry.

Abstract: A device and method for a full-duplex transceiver is disclosed. The transceiver includes a transmitter DAC coupled to a transmission channel. The transmit DAC converting a digital transmission signal into an analog transmission signal. The transceiver further includes a receiver connected to the transmission channel. The receiver receives a desired signal and an echo signal, in which the echo signal includes at least a portion of the analog transmission signal. The receiver includes a receiver ADC, a programmable delay line for adjustably delaying a clock signal of the ADC, and a receiver processing circuit for adjusting the delay of the clock signal based at least in part upon the echo signal.

Abstract: An device and method for a pre-sampling processing is disclosed. The pre-sampling device includes a single amplifier having a virtual ground node, and a feed back circuit connected from an output of the amplifier to the virtual ground node. The feed back circuit includes a plurality of switches connected to the virtual ground node. The switches control a plurality of programmable gain settings. The feed back circuit also includes an adjustable current source that is adjusted according to an estimated echo signal. A current of the adjustable current source is summed at the virtual ground node. The feed back circuit also includes a low pass filter that is tuned to suppress received signal frequencies above a fraction of a sampling frequency of a sampler connected to the pre-sampling device.

Abstract: The invention includes a full duplex transceiver for transmitting and receiving communication signals. The transceiver includes 1 to N sample and hold circuits. Each sample and hold circuit receives a first signal that includes a far-end signal, and in some cases an echo signal, and in some cases alternatively or additionally cross-talk signals. The transceiver additionally includes a plurality of subtraction circuits. Each subtraction circuit receives an output of at least one of the sample and hold circuits. Each subtraction circuit subtracts at least a fraction of a replica signal from at least a fraction of the output of the at least one of the sample and hold circuits. The subtraction circuits generate an output that represent the far-end signal with substantially reduced echo and/or cross-talk interference, and is available for additional receiver processing.

Abstract: A CMOS gain stage includes biasing circuitry configured to insure saturation of a subsequent stage without a source follower circuit. The CMOS gain stage is optionally powered by a supply voltage that is greater than a permitted supply voltage for a processes technology that is used to fabricate the CMOS gain stage. In order to protect CMOS devices within the CMOS gain stage, optional drain-to-bulk junction punch-through protection circuitry is disclosed. A variety of optional features can be implemented alone and/or in various combinations of one another. Optional features include process-voltage-temperature (“PVT”) variation protection circuitry, which renders a gain relatively independent of process, voltage, and/or temperature variations. Optional features further include bandwidth enhancement circuitry.

Abstract: A high-speed sampling system and an analog to digital converter are disclosed. One embodiment of a method of sampling a signal includes receiving an analog signal and generating first samples at a rate of Fs, and generating second sub-samples from the first samples at a rate of Fs/N and having a relative phase of approximately (360/N)*(i?1) degrees, where i varies from 1 to N. In a first embodiment, at most two second sub-samplers are tracking the output of the first sampler at any point in time. In a second embodiment, only one of the N second sub-samplers are tracking the output of the first sampler at any point in time. A third embodiment further includes generating third samples from the second samples at a rate of Fs/N, and having a relative phase of approximately ((360/N)*(i?1)+180) degrees. A method of interleaved analog to digital converting includes corresponding time interleaved ADCs receiving the third samples.

Abstract: An apparatus and method for high-speed analog to digital conversion are disclosed. An ADC system includes a plurality of N/2 sub-ADCs, each sub-ADC receiving an analog signal and a clock signal and generating two digital samples at a rate of Fs/N. The two digital samples are generated with approximately 180 degree phase relationship relative to a frequency of Fs/N. The plurality of N/2 sub-ADCs of the time-interleaved ADC system, generate combined output samples at a rate of Fs. An ADC method includes a plurality of N/2 sub-ADCs receiving the analog signal, clocking each sub-ADC at a rate of FS/N. Each sub-ADC generates two digital samples at a rate of FS/(2N), the two digital samples being generated with approximately 180 degree phase relationship relative to a frequency of Fs/N. Outputs of the sub-ADCs are combined to generate digital samples at a rate of Fs.

Abstract: A high-speed sampling system and an analog to digital converter are disclosed. One embodiment of a method of sampling a signal includes receiving an analog signal and generating first samples at a rate of Fs, and generating second sub-samples from the first samples at a rate of Fs/N and having a relative phase of approximately (360/N)*(i?1) degrees, where i varies from 1 to N. In a first embodiment, at most two second sub-samplers are tracking the output of the first sampler at any point in time. In a second embodiment, only one of the N second sub-samplers are tracking the output of the first sampler at any point in time. A third embodiment further includes generating third samples from the second samples at a rate of Fs/N, and having a relative phase of approximately ((360/N)*(i?1)+180) degrees. A method of interleaved analog to digital converting includes corresponding time interleaved ADCs receiving the third samples.

Abstract: A CMOS gain stage includes biasing circuitry configured to insure saturation of a subsequent stage without a source follower circuit. The CMOS gain stage is optionally powered by a supply voltage that is greater than a permitted supply voltage for a processes technology that is used to fabricate the CMOS gain stage. In order to protect CMOS devices within the CMOS gain stage, optional drain-to-bulk junction punch-through protection circuitry is disclosed. A variety of optional features can be implemented alone and/or in various combinations of one another. Optional features include process-voltage-temperature (“PVT”) variation protection circuitry, which renders a gain relatively independent of process, voltage, and/or temperature variations. Optional features further include bandwidth enhancement circuitry.

Abstract: A method and system is described for managing the development of software source code, and in addition, collecting useful metrics about the development process. A first source code is provided in a desired state. The desired state may be the requirement that the source code can be built or the desired state may be the requirement that the source code can be built and pass one or more tests. A second source code is then received. The second source may be a modified copy of the source code. It is then determined whether the second source code is in the desired state, and the first source code is updated using the second source code in response to the second source code being in the desired state. Metrics that may be collected include: the name of a task, time to complete the task, line of code involved, etc.

Abstract: An automobile includes a door, inner and outer rocker panels, and a floor pan joined to the inner rocker panel. A structural frame extends under the body. A frame standoff member is mounted to the inner rocker panel and extends inboard to a frame rail. The frame standoff member is separated from the frame rail by a clearance gap. Once the gap is closed due to lateral deformation of the door, rocker panels, and floor pan, the frame standoff member will resist further deformation of the door and rocker panels without dynamically coupling the door or rocker panels to the frame rail during normal operation of the vehicle.

Abstract: A CMOS gain stage includes biasing circuitry configured to insure saturation of a subsequent stage without a source follower circuit. The CMOS gain stage is optionally powered by a supply voltage that is greater than a permitted supply voltage for a processes technology that is used to fabricate the CMOS gain stage. In order to protect CMOS devices within the CMOS gain stage, optional drain-to-bulk junction punch-through protection circuitry is disclosed. A variety of optional features can be implemented alone and/or in various combinations of one another. Optional features include process-voltage-temperature (“PVT ”) variation protection circuitry, which renders a gain relatively independent of process, voltage, and/or temperature variations. Optional features further include bandwidth enhancement circuitry.

Abstract: A circuit and method for obtaining a stable delay for a clock signal comprises a current source to generate a constant current having a first value; first and second current over capacitance (I/C) stages coupled to the current source and between a supply voltage and ground; and a capacitor, having a second value and coupled to a node formed by an output of the first I/C stage and an input of the second I/C stage. Application of a clock signal to an input of the first I/C stage produces an output at a logic gate coupled to an output of the second I/C stage. The output has a stable delay based on the first and second values. Additionally, the first and second values (i.e., the value of the current or capacitance) can be changed to achieve a desired amount of the delay applied to the input clock signal.