Systems, apparatuses, and methods for conveying and receiving information as electrical signals in a computing system are disclosed. A computing system includes multiple transmitters sending singled-ended data signals to multiple receivers. A termination voltage is generated and sent to the multiple receivers. The termination voltage is coupled to each of signal termination circuitry and signal sampling circuitry within each of the multiple receivers. Any change in the termination voltage affects the termination circuitry and affects comparisons performed by the sampling circuitry. Received signals are reconstructed at the receivers using the received signals, the signal termination circuitry and the signal sampling circuitry.

Systems and methods are described for transmitting data over physical channels to provide a high bandwidth, low latency interface between integrated circuit chips with low power utilization. Communication is performed using group signaling over multiple wires using a vector signaling code, where each wire carries a low-swing signal that may take on more than two signal values.

Systems, apparatuses, and methods for conveying and receiving information as electrical signals in a computing system are disclosed. A computing system includes multiple transmitters sending singled-ended data signals to multiple receivers. A termination voltage is generated and sent to the multiple receivers. The termination voltage is coupled to each of signal termination circuitry and signal sampling circuitry within each of the multiple receivers. Any change in the termination voltage affects the termination circuitry and affects comparisons performed by the sampling circuitry. Received signals are reconstructed at the receivers using the received signals, the signal termination circuitry and the signal sampling circuitry.

Systems, apparatuses, and methods for conveying and receiving information as electrical signals in a computing system are disclosed. A computing system includes multiple transmitters sending singled-ended data signals to multiple receivers. A termination voltage is generated and sent to the multiple receivers. The termination voltage is coupled to each of signal termination circuitry and signal sampling circuitry within each of the multiple receivers. Any change in the termination voltage affects the termination circuitry and affects comparisons performed by the sampling circuitry. Received signals are reconstructed at the receivers using the received signals, the signal termination circuitry and the signal sampling circuitry.

This document discusses, among other things, apparatus and methods for an edge rate driver for a power converter switch. In an example, the driver can include an input node configured to receive a pulse width modulated signal, a first switch configured to couple a control node of the power converter switch to a supply voltage during a first state, a second switch configured to couple the control node of the power converter switch to a reference voltage during a second state, and a first current source configured to supply charge current to the first switch when the power converter switch transitions from the second state to the first state, the charge current configured to charge a parasitic capacitance of the power converter switch.

Systems, methods, and apparatus for biasing a high speed and high voltage driver using only low voltage transistors are described. The apparatus and method are adapted to control biasing voltages to the low voltage transistors such as not to exceed operating voltages of the low voltage transistors while allowing for DC to high speed operation of the driver at high voltage. A stackable and modular architecture of the driver and biasing stages is provided which can grow with a higher voltage requirement of the driver. Capacitive voltage division is used for high speed bias voltage regulation during transient phases of the driver, and resistive voltage division is used to provide bias voltage at steady state. A simpler open-drain configuration is also presented which can be used in pull-up or pull-down modes.

An apparatus includes a first input/output (I/O) interface circuit having a maximum voltage rating. The first I/O interface circuit includes a level shifter and an output stage. A reference voltage bias generator is coupled to the first I/O interface circuit, to a first supply voltage, and to a first ground potential. The reference voltage bias generator is configured to generate a plurality of reference bias signals, including a first reference voltage and a second reference voltage. When the first supply voltage is not greater than the maximum voltage rating, the first reference voltage is equal to the first supply voltage and the second reference voltage is equal to the first ground potential. When the first supply voltage is greater than the maximum voltage rating, the first reference voltage is equal to the first supply voltage times a first fraction, and the second reference voltage is equal to the first supply voltage times a second fraction.

A method for selecting components in a radiation tolerant electronic system, comprising, determining ionizing radiation responses of COTS devices under various radiation conditions, selecting a subset of the COTS devices whose radiation responses satisfy threshold radiation levels, applying mathematical models of the COTS devices for post-irradiation conditions to determine radiation responses to ionizing radiation; implementing a radiation-tolerant architecture using COTS devices from the selected subset, the implemented circuit may be tested for robustness to ionizing radiation effects without repeated destructive tests of the hardware circuit by using the mathematical models for simulating response to the ionizing radiation, and implementing a multi-layer shielding to protect the implemented circuit under various radiation conditions.

A method for selecting components in a radiation tolerant electronic system, comprising, determining ionizing radiation responses of COTS devices under various radiation conditions, selecting a subset of the COTS devices whose radiation responses satisfy threshold radiation levels, applying mathematical models of the COTS devices for post-irradiation conditions to determine radiation responses to ionizing radiation; implementing a radiation-tolerant architecture using COTS devices from the selected subset, the implemented circuit may be tested for robustness to ionizing radiation effects without repeated destructive tests of the hardware circuit by using the mathematical models for simulating response to the ionizing radiation, and implementing a multi-layer shielding to protect the implemented circuit under various radiation conditions.

A driving circuit includes: a primary driver configured to receive a first signal and generate a second signal based on the first signal, driving capability of the second signal being greater than that of the first signal; and an auxiliary driver connected to an output terminal of the primary driver and configured to receive the first signal and generate an auxiliary driving signal based on the first signal, the auxiliary driving signal being configured to shorten a rise time of the second signal.