Abstract: Systems and methods for simulation forecasting in target networks including dynamic realignment are disclosed. A set of target nodes including at least one demand node realignment representative of a demand volume shift for at least one corresponding distribution node in a predetermined time period is received. When the demand volume shift is equal to or above a predetermined threshold, an estimated volume feature for the at least one corresponding distribution node is generated. When the demand volume shift is below the predetermined threshold, an actual volume feature for the at least one corresponding distribution node is generated. The generated one of the estimated volume feature or the actual volume feature is provided to a trained forecasting model to generate a demand forecast data structure based on the generated one of the estimated volume feature or the actual volume feature.

Abstract: A controller area network including one or more first network nodes biased from a first power supply voltage, and a second network node biased from a second, lower, power supply voltage. The second network node includes a transmitter driving a differential voltage onto bus lines to communicate a dominant bus state at a second dominant state common mode voltage, a receiver coupled to the bus lines, sense circuitry to sense a common mode voltage at the bus lines, and control circuitry to control a recessive state common mode voltage in response to the sensed dominant state common mode voltage.

Abstract: In an example, a CAN transceiver includes a first transistor having a control terminal, having a drain coupled to a voltage supply terminal, and having a source. The CAN transceiver includes a second transistor having a drain coupled to a control terminal of the first transistor, a source coupled to the source of the first transistor, and a control terminal. The CAN transceiver includes a bias circuit coupled to the control terminal of the second transistor, the second transistor configured to convert the first transistor to a diode configuration responsive to detecting high voltage noise.

Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed to buffer an input voltage. An example apparatus includes first inverter circuitry to invert the input voltage and produce a first inverted voltage; second inverter circuitry coupled to the first inverter circuitry, the second inverter circuitry to invert the first inverted voltage and produce a second inverted voltage at a rate based on a first current controlled transistor; third inverter circuitry coupled to the second inverter circuitry, the third inverter circuitry to invert the second inverted voltage and produce a third inverted voltage at a rate based on a second current controlled transistor; and fourth inverter circuitry coupled to the third inverter circuitry, the fourth inverter circuitry to invert the third inverted voltage and produce an output voltage, wherein the output voltage matches the input voltage.

Abstract: An analog duty-cycle detector includes: off-time detection circuitry; on-time detection circuitry; compare circuitry; and a controller. The off-time detection circuitry includes a first transistor and a first capacitor. The on-time detection circuitry includes a second transistor and a second capacitor. The compare circuitry has a first terminal, a second terminal, and a third terminal. The first terminal of the compare circuitry is coupled to a first terminal of the first capacitor. The second terminal of the compare circuitry is coupled to a first terminal of the second capacitor. The controller has a first terminal and a second terminal. The first terminal of the controller coupled to a control terminal of the first transistor. The second terminal of the controller coupled to the control terminal of the second transistor.

Abstract: Differential signaling transmitter circuitry includes upper and lower driver stacks, each with at least one upper blocking transistor and a bias transistor, further includes first and second control loops. A first control loop includes a replica stack including replicas of the bias transistor and blocking transistors of a first one of the driver stacks, and a second control loop includes replica stacks, one with replicas of the bias and blocking transistors of the upper driver stack and one with replicas of the bias and blocking transistors of the lower driver stack. One of the replica stacks in the second control loop receives an output from the first control loop. First and second switching circuitry couples outputs of the first and second control loops to gates of bias transistor in the upper and lower driver stacks, respectively, responsive to a data signal.

Abstract: A positive overshoot detection circuit comprises a transistor coupled to a current mirror, a reference current source coupled to the current mirror, and a comparator coupled to the reference current source and the current mirror. The comparator output indicates whether the current mirror's current is greater than the reference current source's current. A control input and a current terminal of the transistor are coupled to a clamping circuit. A negative overshoot detection circuit comprises a biasing sub-circuit coupled to a transistor, a resistor coupled to the transistor, and a comparator coupled to the transistor and the resistor. The comparator output indicates whether the transistor is in an on or off state. The biasing sub-circuit is coupled to a clamping circuit. In some implementations, the comparator outputs from the positive and negative overshoot detection circuits are provided to a driver circuit, which modifies its operation.

Abstract: A positive overshoot detection circuit comprises a transistor coupled to a current mirror, a reference current source coupled to the current mirror, and a comparator coupled to the reference current source and the current mirror. The comparator output indicates whether the current mirror's current is greater than the reference current source's current. A control input and a current terminal of the transistor are coupled to a clamping circuit. A negative overshoot detection circuit comprises a biasing sub-circuit coupled to a transistor, a resistor coupled to the transistor, and a comparator coupled to the transistor and the resistor. The comparator output indicates whether the transistor is in an on or off state. The biasing sub-circuit is coupled to a clamping circuit. In some implementations, the comparator outputs from the positive and negative overshoot detection circuits are provided to a driver circuit, which modifies its operation.

Abstract: A controller area network including one or more first network nodes biased from a first power supply voltage, and a second network node biased from a second, lower, power supply voltage. The second network node includes a transmitter driving a differential voltage onto bus lines to communicate a dominant bus state at a second dominant state common mode voltage, a receiver coupled to the bus lines, sense circuitry to sense a common mode voltage at the bus lines, and control circuitry to control a recessive state common mode voltage in response to the sensed dominant state common mode voltage.

Abstract: Methods, apparatus, systems, and articles of manufacture are disclosed to buffer an input voltage. An example apparatus includes first inverter circuitry to invert the input voltage and produce a first inverted voltage; second inverter circuitry coupled to the first inverter circuitry, the second inverter circuitry to invert the first inverted voltage and produce a second inverted voltage at a rate based on a first current controlled transistor; third inverter circuitry coupled to the second inverter circuitry, the third inverter circuitry to invert the second inverted voltage and produce a third inverted voltage at a rate based on a second current controlled transistor; and fourth inverter circuitry coupled to the third inverter circuitry, the fourth inverter circuitry to invert the third inverted voltage and produce an output voltage, wherein the output voltage matches the input voltage.

Abstract: An electrical device includes an integrated circuit having device circuitry, a passive breakdown protection circuit, and a resistor coupled to or included with the device circuitry. The resistor includes: a polysilicon layer coupled between a first terminal and a second terminal; an epitaxial layer terminal; and a buried layer terminal. The passive breakdown protection circuit is coupled between the second terminal and the epitaxial layer terminal. The passive breakdown protection circuit is also coupled between the epitaxial layer terminal and the buried layer terminal.

Abstract: A driver includes an open drain output transistor, a capacitor, a first current source, and first and second transistors. Upon assertion of a transmit signal to turn on the first transistor, a controller asserts a second control signal to turn on the second transistor responsive to a voltage of the capacitor being less than a threshold voltage of the open drain output transistor to thereby increase the control terminal voltage for the open drain output transistor at a first time rate. The controller deasserts the second control signal to turn off the second transistor responsive to the capacitor voltage exceeding the threshold voltage. Responsive to the capacitor's voltage exceeding the threshold, the first current source charges the capacitor to further increase the control terminal voltage at a second time rate that is smaller than the first time rate.

Abstract: Two CAN bus transceivers utilized in a single integrated circuit package with the CAN bus connections between the two transceivers being inverted. Thus, one transceiver is connected to the CAN bus high and low lines while the other transceiver is connected to the CAN bus low and high lines. Both transceivers power up in a standby condition and each transceiver is monitoring for wake up signals on the CAN bus. The transceiver that is correctly connected to the CAN bus detects wake up signals. When the wake up signals are detected at that transceiver, that transceiver is brought to full operating state and the other transceiver is placed in a full standby condition. Additional input resistance is provided with each transceiver to maintain the proper input resistance for the integrated circuit.

Abstract: An electrical device includes an integrated circuit having device circuitry, a passive breakdown protection circuit, and a resistor coupled to or included with the device circuitry. The resistor includes: a polysilicon layer coupled between a first terminal and a second terminal; an epitaxial layer terminal; and a buried layer terminal. The passive breakdown protection circuit is coupled between the second terminal and the epitaxial layer terminal. The passive breakdown protection circuit is also coupled between the epitaxial layer terminal and the buried layer terminal.

Abstract: A positive overshoot detection circuit comprises a transistor coupled to a current mirror, a reference current source coupled to the current mirror, and a comparator coupled to the reference current source and the current mirror. The comparator output indicates whether the current mirror's current is greater than the reference current source's current. A control input and a current terminal of the transistor are coupled to a clamping circuit. A negative overshoot detection circuit comprises a biasing sub-circuit coupled to a transistor, a resistor coupled to the transistor, and a comparator coupled to the transistor and the resistor. The comparator output indicates whether the transistor is in an on or off state. The biasing sub-circuit is coupled to a clamping circuit. In some implementations, the comparator outputs from the positive and negative overshoot detection circuits are provided to a driver circuit, which modifies its operation.

Abstract: A driver includes an open drain output transistor, a capacitor, a first current source, and first and second transistors. Upon assertion of a transmit signal to turn on the first transistor, a controller asserts a second control signal to turn on the second transistor responsive to a voltage of the capacitor being less than a threshold voltage of the open drain output transistor to thereby increase the control terminal voltage for the open drain output transistor at a first time rate. The controller deasserts the second control signal to turn off the second transistor responsive to the capacitor voltage exceeding the threshold voltage. Responsive to the capacitor's voltage exceeding the threshold, the first current source charges the capacitor to further increase the control terminal voltage at a second time rate that is smaller than the first time rate.

Abstract: A system includes a controller area network (CAN) transceiver. The CAN transceiver includes a wake-up circuit having an attenuator circuit coupled to a CAN bus. The wake-up circuit also includes a common-gate amplifier circuit coupled to the attenuator circuit. The wake-up circuit also includes an offset generation circuit coupled to the common-gate amplifier circuit.

Abstract: A system includes a controller area network (CAN) transceiver. The CAN transceiver includes a wake-up circuit having an attenuator circuit coupled to a CAN bus. The wake-up circuit also includes a common-gate amplifier circuit coupled to the attenuator circuit. The wake-up circuit also includes an offset generation circuit coupled to the common-gate amplifier circuit.

Abstract: A bus transceiver circuit including a current source device, a current mirror coupled to the current source device, and a first transistor having a first control input and first and second current terminals. The bus transceiver circuit also includes a second transistor having a second control input and third and fourth current terminals. The third current terminal is coupled to the first control input at a first node. The fourth current terminal is coupled to the current mirror. A resistor is coupled between the first current terminal and the first node.

Abstract: A driver includes an open drain output transistor, a capacitor, a first current source, and first and second transistors. Upon assertion of a transmit signal to turn on the first transistor, a controller asserts a second control signal to turn on the second transistor responsive to a voltage of the capacitor being less than a threshold voltage of the open drain output transistor to thereby increase the gate voltage for the open drain output transistor at a first time rate. The controller deasserts the second control signal to turn off the second transistor responsive to the capacitor voltage exceeding the threshold voltage. Responsive to the capacitor's voltage exceeding the threshold, the first current source charges the capacitor to further increase the gate voltage at a second time rate that is smaller than the first time rate.