Abstract: A reference-corrected ratiometric current sensing circuit for sensing a current flowing through a load and a power-controlling pass device includes a sense device, a sense resistor, and a variable reference current source for providing a varying reference current. The varying reference current is varied according to a ratio of the voltage across the sense device to the voltage across the pass device. The ratiometric current sensing circuit of the present invention is capable of accurate current sensing in spite of disparities that may occur between the voltages across the sense and the pass devices. In one embodiment, the variable reference source includes a transconductance amplifier circuit that provides an output current indicative of the voltage difference at its input terminals.

Abstract: An integrated circuit fabrication process includes a selective substrate implant process to effectively decouple a first power supply connection from a second power supply connection while providing immunity against parasitic effects. In one embodiment, the selective substrate implant process forms heavily doped p-type regions only under P-wells in which noise producing circuitry are built. The noisy ground connection for these P-wells are decoupled from the quiet ground connection for others P-wells not connected to any heavily doped regions and in which noise sensitive circuitry are built. The selective substrate implant process of the present invention has particular applications in forming CMOS analog integrated circuits where it is important to decouple the analog ground for sensitive analog circuitry from the often noisy digital grounds of the digital and power switching circuitry.

Abstract: A single chip superheterodyne AM receiver is disclosed herein. The receiver has a control pin for application of control signals to adjust a frequency response of a baseband filter to tailor its frequency response to a particular type of signal received by the receiver. Various techniques are described for enabling a complete superheterodyne AM receiver to be implemented on a single chip which receives an antenna input signal and outputs a digital data signal.

Abstract: A universal serial bus transceiver is disclosed. In one embodiment, the transceiver includes a differential transmitting amplifier with a first input terminal that receives a reference voltage, a second input terminal that receives a first data input signal at a level corresponding to the reference voltage, and a third input terminal that receives a second data input signal at the reference voltage level. The differential transmitting amplifier generates first and second bus data output signal at the bus signal level in response to the first and second data input signals. The transceiver also includes a first receiving amplifier with a first input terminal that receives the reference voltage and a second input terminal that receives a first bus data input signal at the bus signal level. The first receiving amplifier generates a first data output signal at the reference voltage level.

Abstract: A fan speed control system for controlling the operation and speed of a fan is described. The fan speed control system includes a power control block for supplying an output voltage to the fan. An integrated circuit fan controller causes a resistor divider circuit to operably divide a selected portion of the output voltage. The integrated circuit fan controller comprises a data register which receives values indicative of control or speed operands from a host. A logic state machine translates these values into appropriate logic signals and provides the signals to the resistor divider circuit. A timing reference or an oscillator controls the proper sequencing and timing relationship of the logic state machine. To turn the fan on, the following sequence of steps occurs. The power control block is turned off causing the output voltage not to be supplied to the fan. The logic state machine controls the resistor divider circuit to divide the output voltage to be supplied to the fan.

Abstract: A superhetrodyne AM receiver and digital decoder are formed on the same chip. The frequency responses of the various filters are tied to the reference frequency. To compensate for process variations in the implementation of the IC, bias currents setting the operating conditions for various amplifiers, filters, and other components in the system are adjusted based on frequency control signal in a PLL circuit in the local oscillator. Since the magnitude of the control signal reflects the process variations, the bias currents are adjusted based on the control signal to offset these variations in other portions of the receiver. To further improve the signal to noise ratio of the receiver. The IF filter is tuned within a range so as not to include any integer multiple or integer divisor of the timing reference frequency. Various techniques are described for enabling a complete superhetrodyne AM receiver to be implemented on a single chip which receives an antenna input signal and outputs a digital data signal.

Abstract: A driver circuit for alternately driving a first transistor and a second transistor connected in series includes primary and secondary anti-shoot-through protection. The driver circuit prevents shoot-through at the first and second transistors by using a pair of switch lock-out signals. The switch lock-out signals prevent one transistor from turning on until the other transistor is turned off. The driver circuit eliminates shoot-through in the driver devices driving the first and second transistors by using a pair of driver lock-out signals. The driver devices are turned on only briefly during the transitions of the first and second transistors. Otherwise, the driver devices are turned off. The driver lock-out signals ensure that no contention occurs between the driver devices and furthermore, set up the driver devices for the next On-Off switching sequence. The driver circuit can achieve a fast switching operation as well as improve the efficiency of the power transistors.

Abstract: A compensation circuit for introducing a zero in a first circuit being incorporated in a closed loop feedback system includes a first capacitor, an amplifier and a second capacitor, connected in series between a feedback terminal and an input node of the first circuit. A first resistor is coupled between the feedback terminal and the input node to provide a resistive load to the compensation circuit. The amplifier amplifies the capacitance of the second capacitor to introduce a zero in the first circuit having effectiveness over a wide frequency range. In one embodiment, the compensation circuit is applied to a switching regulator controller for adding an effective zero in the feedback system of a switching regulator for compensating a double-pole introduced by a LC filter circuit in the switching regulator feedback system.

Abstract: A reference-corrected ratiometric current sensing circuit for sensing a current flowing through a load and a power-controlling pass device includes a sense device, a sense resistor, and a variable reference current source for providing a varying reference current. The varying reference current is varied according to a ratio of the voltage across the sense device to the voltage across the pass device. The ratiometric current sensing circuit of the present invention is capable of accurate current sensing in spite of disparities that may occur between the voltages across the sense and the pass devices. In one embodiment, the variable reference source includes a transconductance amplifier circuit that provides an output current indicative of the voltage difference at its input terminals. Furthermore, the variable reference current source includes a translinear circuit that works with the transconductance amplifier circuit to implement the prescribed arithmetic operations to generate the varying reference current.

Abstract: A voltage monitor circuit for monitoring a first voltage includes a switch and a comparator. The switch has a first position and a second position. When the switch is in the first position, the switch connects the comparator to a first voltage terminal to monitor a second voltage. When the switch is in the second position, the switch connects the comparator to a second voltage terminal to monitor a third voltage. The second and third voltages are scaled voltages of the first voltage to be monitored. The comparator provides an output signal indicating a status of the first voltage, that is, whether the first voltage is within an operative range. The voltage monitor circuit may further include a voltage divider connected between the first voltage and a ground potential. The voltage monitor circuit of the present invention can be incorporated in an electrical system for monitoring a battery voltage.

Abstract: A single chip superhetrodyne AM receiver is disclosed herein. To compensate for process variations in the implementation of the IC, bias currents setting the operating conditions for various amplifiers and other components in the system are adjusted based on frequency control signals in a PLL circuit in the local oscillator. Since the magnitude of the control signal reflects the process variations, the bias currents are adjusted based on the control signal to offset these variations in other portions of the receiver. To further improve the signal to noise ratio of the receiver, the IF filter is tuned within a range so as not to include any integer multiple or integer divisor of the timing reference frequency. Various techniques are described for enabling a complete superhetrodyne AM receiver to be implemented on a single chip which receives an antenna input signal and outputs a digital data signal.

Abstract: A controller for limiting the current through a pass transistor is described herein that includes an NMOS control transistor coupled between the gate of the pass transistor and ground. The gate of the NMOS control transistor is coupled to a bootstrap circuit via a PMOS transistor. The PMOS transistor is turned on in the event of a current limit signal to momentarily apply the bootstrap voltage to the gate of the NMOS control transistor. This quickly turns on the NMOS control transistor to discharge the gate of the pass transistor, shutting off the pass transistor and terminating the high current situation. After the bootstrapped voltage has been shunted to ground, a reverse biased diode allows the gate of the NMOS control transistor to remain charged to keep the NMOS control transistor on. After the current limit situation has passed, the NMOS control transistor is switched off.

Abstract: A monolithic AM transmitter is disclosed. An external antenna forms part of a resonance network so that the antenna resonance point is automatically tuned to the transmit frequency. This provides flexibility with no added cost to the transmitter.

Abstract: A differential pair includes a first and second transistors each having a control terminal coupled to a first input voltage, and a third and fourth transistors each having a control terminal coupled to a second input voltage. The first, second, third, and fourth transistors each has a first current handling terminal coupled to a reference voltage. The first and second transistors each has a second current handling terminal coupled to a first current mirror. The third and fourth transistors each has a second current handling terminal coupled to a second current mirror. A resistor is coupled between the second current handling terminals of the second and third transistors. The differential pair is capable of attaining a high slew rate and a possible common mode input voltage of ground while drawing only a small quiescent current.

Abstract: A switching regulator for reducing electromagnetic interference (EMI) includes a PWM controller which incorporates a varying frequency oscillator for controlling the operating frequency of the switching regulator. The varying frequency oscillator provides an oscillating signal having a continuously varying frequency about the center switching frequency of the switching regulator. The varying frequency oscillating signal causes the operating frequency of the switching regulator to vary, spreading out the EMI noise generated by the switching regulator and effectively reducing the peak energy of the EMI noise.

Abstract: A single chip superhetrodyne AM receiver including a local oscillator which sweeps through a frequency range at a rate higher than a modulation frequency of the incoming RF signal. The local oscillator frequency is mixed with the incoming RF signal. An IF filter passes a selected frequency band from the mixer to a demodulator. The demodulator is tuned to demodulate any signal within a band of frequencies determined by the sweeping of the local oscillator. This increases the signal to noise ratio of the receiver since it allows for variations in the transmitter output frequency. The frequency responses of the various filters are tied to the reference frequency and allows the user to set the tuning and alignment of the receiver. To compensate for process variations in the implementation of the IC, bias currents setting the operating conditions for various amplifiers and other components in the system are adjusted based on frequency control signals in a PLL circuit in the local oscillator.

Abstract: A start-up circuit for voltage regulators includes a depletion mode field effect transistor (FET) having a drain electrically coupled to an input voltage, a source electrically coupled to the voltage regulator power supply input terminal and to a voltage corresponding to an output voltage of the voltage regulator, a body at a fixed voltage, and a gate electrically coupled to the output of a comparator. At start-up, the voltage regulator is powered through the FET. The drain current is self-limiting, preventing the source of the FET from rising to the level of the input voltage. When the rising output voltage of the regulator reaches a level that can operate the regulator control circuit, the comparator grounds the gate of the FET to turn off the FET, and the voltage regulator operates off of its own output. Virtually no power is dissipated in the FET during steady-state operation of the regulator.

Abstract: A voltage reference circuit includes a first transistor and a second transistor having their control terminals connected together, a first resistor coupled to a first current handling terminal of the first transistor, a second resistor coupled between an output node and a second current handling terminal of the second transistor, and a current mirror. The reference circuit provides an output voltage that is independent of variations in the supply voltage by adjusting the resistance of the first resistor in response to changes in the supply voltage. In one embodiment, the voltage at the control terminals of the first and second transistors is kept constant despite variations in the supply voltage. A first current and a second current flowing through the first and second transistors are also kept constant.

Abstract: A TTL input stage for negative supply voltage systems is described herein which obviates the need for a positive supply and a level shifter. In one embodiment, a first JFET current source, the emitter/collector of a PNP bipolar transistor, and a second JFET current source are connected in series between a control input and a negative supply voltage. The base of the bipolar transistor is connected to ground. At a control input of 2V.sub.be above ground, the PNP transistor has a V.sub.be drop across its emitter/base junction, and each of the identical JFETs has a V.sub.be drop across it. An NPN bipolar transistor, having its base connected to the source of the second JFET and its emitter connected to the negative voltage, is turned on by the V.sub.be drop across the second JFET to provide the output of the TTL input stage. In one embodiment, the TTL input stage is a control circuit for turning an output MOSFET on and off.

Abstract: A resistivity map is prepared depicting the sheet resistance of a resistive film formed on a wafer as a function of position on the wafer. The resistivity map includes a plurality of zones each of which encompasses a specific range of resistivities of the resistive film. A mask containing numerous patterns which define associated resistors in the resistive film is divided into a plurality of zones which correspond to the plurality of zones of the resistivity map. One or more of the dimensions of the resistor patterns within each zone of the mask is automatically altered in a manner so as to compensate for the resistivity range of the corresponding zone of the resistivity map. Thus, in those portions of the resistive film where the sheet resistance is higher than the film's intended value, the width of the patterns in corresponding portions of the resistor mask are increased by an appropriate amount, thereby compensating for the higher sheet resistance.