Abstract: A method relates generally to comparison of a communications system modelled with a behavioral model and implemented with a circuit realization. In this method, operation of the communications system is simulated with the behavioral model on a computing device to obtain a first pulse response. The simulating includes first equalizing first data with a first equalizer of the behavioral model to obtain the first pulse response. The circuit realization is operated to obtain a second pulse response. The operating includes: second equalizing second data corresponding to the first data with a second equalizer of the circuit realization to obtain the second pulse response. The second pulse response from the circuit realization is loaded to memory of the computing device. The first pulse is loaded to the memory of the computing device. The first pulse response and the second pulse response are compared with one another by the computing device.

Abstract: In an exemplary system, a first sampling circuit is coupled to a clock module to receive values therefrom. A second sampling circuit is coupled to the clock module to receive the values therefrom. The first sampling circuit includes a first converter, a first phase interpolator, and a first sampler. The first converter is coupled to replace the values with first replacement values for input to the first phase interpolator. The second sampling circuit includes a second converter, a second phase interpolator, and a second sampler. The second converter is coupled to replace the values with second replacement values for input to the second phase interpolator.

Abstract: A receiver in an integrated circuit device is described. The circuit comprises a receiver having a clock and data recovery circuit coupled to receive data signals modulated with a transmitter clock signal; and a clock generator coupled to receive an output of the clock and data recovery circuit, the clock generator providing a modulated reference clock to the receiver, based upon a reference clock signal which is independent of the transmitter clock signal; wherein the modulated reference clock provided to the receiver is synchronized with the transmitter clock signal. A method of receiving data in an integrated circuit is also described.

Abstract: In an apparatus, a receiver includes a clock data recovery module to provide a dense distribution of waveform edges across an adjustment range, and an eye scan circuit to obtain samples at a first sample position and a second sample position to provide an error count for a sample count for the samples. An eye scan module, coupled to the receiver, is configured to: scan for the samples at the first sample position of a first type for each of a plurality of sample positions of a second type to obtain an error count for a sample count for each of the plurality of sample positions; locate a threshold BER from the scan; determine an amount and a direction of a sample offset at the threshold BER from a reference location; and adjust either the first sample position or the second sample position responsive to the amount and the direction.

Abstract: An embodiment of an apparatus for nonlinearity compensation is disclosed. For an embodiment, a pre-distorter is coupled to receive a first signal. The pre-distorter is configured to convert first values of the first signal into second values for a second signal. The pre-distorter includes a converter for converting the first values to the second values. A phase interpolator is coupled to receive the second signal. The second values are associated with nonlinearity of the phase interpolator. The phase interpolator is configured to provide an interpolated output from the second signal. The second signal is adjusted for the nonlinearity of the phase interpolator by use of the second values.

Abstract: An embodiment of a multichip module is disclosed. For this embodiment of a multichip module, a semiconductor die and an interposer are included. The interposer has conductive layers, dielectric layers, and a substrate. Internal interconnect structures couple the semiconductor die to the interposer. External interconnect structures are for coupling the interposer to an external device. A first inductor includes at least a portion of one or more of the conductive layers of the interposer. A first end of the first inductor is coupled to an internal interconnect structure of the internal interconnect structures. A second end of the first inductor is coupled to an external interconnect structure of the external interconnect structures.

Abstract: In accordance with some embodiments, an integrated circuit device comprises a circuit configured to provide a sense signal representing a dynamic power requirement of the circuit to a first sense node, a first sense switch coupled between the first sense node and a first die bump, and a sense switch controller configured to provide a control signal to the first sense switch.

Abstract: An embodiment of a multichip module is disclosed. For this embodiment of a multichip module, a semiconductor die and an interposer are included. The interposer has conductive layers, dielectric layers, and a substrate. Internal interconnect structures couple the semiconductor die to the interposer. External interconnect structures are for coupling the interposer to an external device. A first inductor includes at least a portion of one or more of the conductive layers of the interposer. A first end of the first inductor is coupled to an internal interconnect structure of the internal interconnect structures. A second end of the first inductor is coupled to an external interconnect structure of the external interconnect structures.

Abstract: A method is provided for transmitting serial data. The method includes receiving successive transmit data words, wherein each transmit data word has a plurality of bits. Each of the plurality of bits in each transmit data word is multiplied into a multiple number of adjacent bits to form an expanded data word. Each of the expanded data words is serialized to form a serial data word stream, which is transmitted.

Abstract: A method is provided for transmitting serial data. The method includes receiving successive transmit data words, wherein each transmit data word has a plurality of bits. Each of the plurality of bits in each transmit data word is multiplied into a multiple number of adjacent bits to form an expanded data word. Each of the expanded data words is serialized to form a serial data word stream, which is transmitted.

Abstract: An over-voltage protected integrated circuit is provided, which includes a discharge node, an input-output pad, a signal trace, which is coupled to the input-output pad, and a pair of back-to-back diodes, which is coupled between the first signal trace and the discharge node.

Abstract: An over-voltage protected integrated circuit is provided, which includes a discharge node, an input-output pad, a signal trace, which is coupled to the input-output pad, and a pair of back-to-back diodes, which is coupled between the first signal trace and the discharge node.

Abstract: A data transmission circuit for transmitting a data stream includes a voltage supply terminal, a resistively terminated, controlled-impedance transmission line and an inductor coupled between the voltage supply terminal and the controlled-impedance transmission line.

Abstract: A serial data transceiver is presented which includes elements which facilitate testing using only the serial data transfer terminals of the transceiver. The serial data transceiver includes a transmitter and a receiver. The transmitter receives parallel data, converts the parallel data to a serial data stream, and transmits the serial data stream. The receiver receives a serial data stream, converts the serial data stream to parallel data, and provides the parallel data. During testing, parallel data produced by the receiver is routed to the transmitter input. In one embodiment, the transmitter includes a first router for routing parallel input data to the transmitter, and the receiver includes a second router for routing parallel output data produced by the receiver. The first router is coupled to the second router, both routers receive a test signal.

Abstract: A serial data transceiver architecture and test method are presented for measuring the amount of jitter within a serial data stream. A transmitter of the transceiver receives parallel input data at a transmit data input port, converts the parallel input data to a serial data stream having data windows separated by data transition periods, and produces the serial data stream at a transmitter output port. A receiver of the transceiver receives a serial data stream at a receiver input port, converts the serial data stream to parallel output data, and provides the parallel output data at a receive data output port.

Abstract: One or more improved transmit units tightly integrated into an enhanced cluster cache with controller. Coherent memory transactions in a loosely coupled computer network are supported by sending all cache updates to all computers in the loosely coupled computer network through high speed, low latency and high bandwidth serial lines linking all computers to all other computers. The cluster cache controller may include a local cache controller and/or as a local bus controller. The local bus controller is operable to coupled the cluster cache to an I/O subsystem. A local cache memory preferably caches data and/or instructions, or locations thereof for the entire computer, making the local computer cache available to the entire computer cluster through the transmit unit. Each transfer unit is a full-duplex transceiver that includes transmitter and receiver functions. Each transfer unit can send and receive data simultaneously since operation of their transmitter and receiver functions are independent.

Abstract: A serial data transceiver is presented which includes elements which facilitate testing using only the serial data transfer terminals of the transceiver. The serial data transceiver includes a transmitter and a receiver. The transmitter receives parallel data, converts the parallel data to a serial data stream, and transmits the serial data stream. The receiver receives a serial data stream, converts the serial data stream to parallel data, and provides the parallel data. During testing, parallel data produced by the receiver is routed to the transmitter input. In one embodiment, the transmitter includes a first router for routing parallel input data to the transmitter, and the receiver includes a second router for routing parallel output data produced by the receiver. The first router is coupled to the second router, both routers receive a test signal.

Abstract: An apparatus and method are presented for testing the ability of a pair of serial data transceivers to transmit serial data at one frequency and to receive serial data at another frequency. A serial communication device of the present invention includes a first and second serial data transceivers and a multiplexer formed upon a monolithic semiconductor substrate. Each serial data transceiver includes a receiver and a transmitter which transmits serial data in response to a clock signal. The second serial data transceiver is coupled to receive a reference clock signal. The multiplexer facilitates testing, and is coupled to the first serial data transceiver. The multiplexer receives the reference clock signal, a test clock signal, and a test signal, and provides either the reference clock signal or the test clock signal to the first transceiver dependent upon the test signal. The reference and test clock signals have different frequencies.

Abstract: A transceiver pair is connected by a plurality of high speed serial lines that are tightly integrated into an enhanced communications system. The communications system includes a base transceiver, a remote transceiver, and a plurality of high speed serial lines operably coupled between them. The base transceiver includes a first base input port for receiving parallel data, a plurality of first base output ports for outputting serialized data and a plurality of base serializers operably coupled between the first base input port and the plurality of first base output ports. The plurality of base serializers convert the parallel data into the serialized data. A base input demultiplexer is operably coupled between the first base input port and the plurality of base serializers.

Abstract: An improved transceiver that is tightly integrated into an enhanced receiving chip for a computer monitor. The transceiver includes a receiver having a first input port for receiving serialized data, a first output port for transmitting deserialized data to the transceiver, and a second input port adapted for receiving feedback data forwarded from a sensor to an audio and video control unit. The serialized data comprises video, audio and control data. The transceiver further comprises a receiver operably coupled between the first input port and the first output port, as well as a timing generator coupled to recover a clock signal from the serialized data and to synchronize the deserialized data from the recovered clock. The transceiver also includes a transmitter with a third input port for receiving parallel data and a second output port for transmitting a serial data stream. The parallel data are received by the third input port concurrently with the serialized data being received by the first input port.