A cable equalizer configured as part of a cable comprising a first stage, a second stage, and a third stage. The first stage comprises a first stage bias current circuit configured to generate a bias current and a pre-emphasis module configured to introduce pre-emphasis into a received signal to counter the effects of signal amplification. Also part of the first stage is a bias voltage circuit configured to provide a bias voltage to the first stage. The second stage comprises a buffer configured impedance match the first stage. The third stage comprises a third stage bias current circuit configured to generate a bias current and a tank equalizer circuit configured to perform frequency specific equalization on a second stage signal. An amplifier is configured to amplify the second stage signal to create an amplified signal, which is output from the cable equalizer by an output driver.

An integrated circuit equalizes a data signal expressed as a series of symbols. The symbols form data patterns with different frequency components. By considering these patterns, the integrated circuit can experiment with equalization settings specific to a subset of the frequency components, thereby finding an equalization control setting that optimizes equalization. Optimization can be accomplished by setting the equalizer to maximize symbol amplitude.

An equalizer circuit includes: a pair of input terminals: a differential amplification circuit outputs, to a pair of output terminals, first signals obtained by amplifying a difference in levels of input signals supplied to the pair of input terminals; and a differential differentiation amplification circuit that outputs, to the pair of output terminals, second signals obtained by amplifying a time-varying change in the difference in the levels of the input signals supplied to the pair of input terminals.

An information handling system may include a plurality of communication destinations, a communication source, a single-source/multi-destination cable having a plurality of branches, each branch communicatively coupling the communication source to a communication destination respective to such branch, and a logic device communicatively coupled to the communication source and the single-source/multi-destination cable and configured to communicate to each of the plurality of branches both analog source identifying information and digital source identifying information regarding the communication source.

A system, a method and circuit arrangements for adjusting an output impedance of an electric circuit involve impedance cells connected to an output terminal in parallel with one another. Each impedance cell includes parallel branches. Each branch includes switching units and resistors. The resistors in a branch are connected in series and contribute to an overall impedance of their corresponding impedance cell. Each switching unit is configurable to selectively bypass a corresponding one of the resistors, thereby calibrating the impedance cell. The output impedance can be set by identifying a combination of calibrated impedance cells that need to be activated in order to produce the target output impedance.

A passive equalizer is provided. The passive equalizer includes a first resistive element, a first inductive element, a second resistive element, and a first variable capacitor. The first resistive element is coupled between an input node and an output node. The first inductive element and the second resistive element are coupled in series between the output node and a first voltage supply node. The first variable capacitor is coupled between the input node and a first node located between the first inductive element and the second resistive element.

A semiconductor device and a serial data transmission line system have a reception circuit and an adaptive equalizer circuit. A supply source of a power supply supplied with the reception circuit is selected based on correction intensity of the correction value calculated by the adaptive equalizer circuit. When correction intensity of the correction value calculated by the adaptive equalizer circuit is not less than a threshold value, the supply source of the power supply supplied to the reception circuit and the adaptive equalizer circuit is switched, and a noise level of the power supply is reduced.

An information handling system may include a plurality of communication destinations, a communication source, a single-source/multi-destination cable having a plurality of branches, each branch communicatively coupling the communication source to a communication destination respective to such branch, and a logic device communicatively coupled to the communication source and the single-source/multi-destination cable and configured to communicate to each of the plurality of branches both analog source identifying information and digital source identifying information regarding the communication source.

Systems, apparatuses, and methods for performing efficient data transfer in a computing system are disclosed. A computing system includes multiple transmitters sending singled-ended data signals to multiple receivers. In order to better handle noise issues when using single-ended signaling, one or more of the receivers include equalization circuitry and termination circuitry. The termination circuitry prevents reflection on a corresponding transmission line ending at a corresponding receiver. The equalization circuitry uses a bridged T-coil circuit to provide continuous time linear equalization (CTLE) with no feedback loop. The equalization circuitry performs equalization by providing a high-pass filter that offsets the low-pass characteristics of a corresponding transmission line. A comparator of the receiver receives the input signal and compares it to a reference voltage. The placement of the comparator and the ratio of the inductances of the inductors of the bridged T-coil circuit are based on whether the receiver includes self-diagnostic circuitry.

A cable equalizer configured as part of a cable comprising a first stage, a second stage, and a third stage. The first stage comprises a first stage bias current circuit configured to generate a bias current and a pre-emphasis module configured to introduce pre-emphasis into a received signal to counter the effects of signal amplification. Also part of the first stage is a bias voltage circuit configured to provide a bias voltage to the first stage. The second stage comprises a buffer configured impedance match the first stage. The third stage comprises a third stage bias current circuit configured to generate a bias current and a tank equalizer circuit configured to perform frequency specific equalization on a second stage signal. An amplifier is configured to amplify the second stage signal to create an amplified signal, which is output from the cable equalizer by an output driver.