| Patent application number | Description | Published |
|---|
| 20080238556 | Simple Technique For Reduction Of Gain In A Voltage Controlled Oscillator - A ring oscillator circuit having an odd plurality of inverter stages (i.e., 2N+1 stages). In accordance with one embodiment of the present invention, only one of the inverter stages is operated in response to a variable input voltage, while the remaining inverter stages are operated in response to a highly filtered constant input voltage. The inverter stages that operate in response to the constant input voltage oscillate at a base frequency. The inverter stage that operates in response to the variable input voltage causes the frequency of the output signal to deviate from the base frequency by an amount determined by the variable input voltage. In this manner, the variable voltage inverter stage implements frequency control for the ring oscillator. The gain of the ring oscillator circuit is reduced by a factor of (2N+1) with respect to the gain of a conventional ring oscillator. | 10-02-2008 |
| 20090102513 | Low Power Output Driver - A low power output driver includes one of a regulated reduced voltage source that receives a supply voltage and outputs a regulated reduced voltage that is a lower voltage than the supply voltage. The driver also includes a first driver input that receives a first logic signal, a second driver input that receives a second logic signal, a first driver output that outputs a first output signal and a second driver output that outputs a second output signal. The driver includes first, second, third and fourth n-type metal oxide semiconductor (NMOS) that are cross-connected between the reduced voltage and the first and second driver outputs or a constant voltage internal ground. When the second input is high, the second NMOS and the third NMOS are gated on, the second driver output is raised to the reduced voltage and the first driver output is pulled down to the constant voltage ground. | 04-23-2009 |
| 20100148840 | PULSE MODULATED CHARGE PUMP CIRCUIT - A circuit for increasing a gate voltage of a transmission gate in a high-speed switch to a level higher than a level of a supply voltage is provided. The circuit includes an oscillator generating a clock signal and a charge pump circuit operatively coupled to the oscillator. The charge pump circuit receives the supply voltage and the clock signal as inputs, and outputs the gate voltage. The circuit also includes a comparator circuit coupled to the oscillator circuit and the charge pump circuit and a pulse signal generator circuit operatively coupled to the oscillator, the pulse signal generator circuit generating a pulse signal which enables the oscillator. | 06-17-2010 |
| 20110057714 | High Voltage Switch Utilizing Low Voltage MOS Transistors with High Voltage Breakdown Isolation Junctions - A high voltage switch having first and second states includes an input receiving an input voltage that is greater than a supply voltage. Each of first, second, and third MOS structures of a first conductivity type has a gate, a source, and a drain. The sources and drains of each of the MOS structures are electrically coupled in series between the input and ground. An output is electrically coupled to the input. When the switch is in the first state, the gate of the first MOS structure is pulled to ground, the gate of the second MOS structure is pulled to the supply voltage, and the gate of the third MOS structure is pulled to a voltage greater than the supply voltage and less than the input voltage. When the switch is in the second state, the gates of all of the MOS structures are pulled to the supply voltage. | 03-10-2011 |
| 20110193600 | Methods of Frequency versus Temperature Compensation of Existing Crystal Oscillators - Methods for compensating the existing crystal oscillator frequencies in extended temperature ranges. These are utilizing existing crystal oscillators on any system design which may have quartz crystals with associated circuitry to deliver frequency or timing reference signals. They are increasing these existing circuitry's accuracy simply by adding small integrated circuit component. | 08-11-2011 |
