Class / Patent application number | Description | Number of patent applications / Date published |
331143000 | RELAXATION OSCILLATORS | 18 |
20090108948 | Relaxation oscillator for compensating system delay - A relaxation oscillator compensates for system delay. The relaxation oscillator includes first and second input signal units that generates first and second capacitor voltages, a delay compensation unit that receives a reference voltage and the first and second capacitor voltages and that generates a compensation voltage. In certain embodiments, a voltage generating unit applies the reference voltage to the delay compensation unit, and a latch unit stores first and second comparison signals compared by the first and second input signal units and transmits a clock signal and a inverted clock signal to the first and second input signal units. The first and second input signal units compare the first and second capacitor voltages with a compensation voltage transmitted from the delay compensation unit. | 04-30-2009 |
20090289733 | METHOD OF FORMING AN OSCILLATOR CIRCUIT AND STRUCTURE THEREFOR - In one embodiment, an oscillator circuit is configured to oscillate at a base frequency. The oscillator is configured to receive a synchronization signal and restart a period of the oscillator signal responsively to the synchronization signal. | 11-26-2009 |
20100090772 | OSCILLATOR WITH DELAY COMPENSATION - In the many microelectronics applications, delays present in circuitry can affect both the design and the function of the circuitry. One example of delays impacting the function of a circuit is a relaxation oscillator, where delays present in comparator circuits and latches can cause its frequency to vary beyond desired ranges. Here, a relaxation circuit with delay compensation is described. | 04-15-2010 |
20100283552 | FLICKER NOISE CANCELLATION IN OSCILLATORS - An oscillator is disclosed. The oscillator includes a first capacitor. The oscillator also includes a second capacitor. The oscillator further includes a first current source. The oscillator also includes a second current source. The oscillator further includes a comparator that has a first input and a second input. The oscillator also includes a reference node. The oscillator further includes a controller that is configured to selectively couple the first current source to the first capacitor and the second current source to the reference node during a first time period. | 11-11-2010 |
20100301957 | RELAXATION OSCILLATOR USING SPINTRONIC DEVICE - Disclosed herein is a relaxation oscillator using a spintronic device. The relaxation oscillator includes a power source unit, a spintronic device, and a capacitor. The power source unit applies power. The spintronic device is driven by the power applied by the power source unit, and has a variable voltage value depending on the intensity of a magnetic field. The capacitor is connected in parallel with the spintronic device, and is discharged when it assumes a minimum-voltage value in the threshold voltage range of the spintronic device and charged when it assumes a maximum voltage value in the threshold voltage range. | 12-02-2010 |
20120126906 | Relaxation Oscillator - A relaxation oscillator and a method for offset cancellation in a relaxation oscillator. The relaxation oscillator comprises two comparator units, each comparator unit comprising a comparator element and a memory element; and a switch control generator coupled to each of the comparator units; wherein each comparator unit, in a reset state, stores an input-offset voltage on the memory element under the control of the switch control generator such that, in a comparison state, the input-offset voltage is applied to both inputs of the comparator for implementing an offset-free threshold. | 05-24-2012 |
20120182080 | PRECISION OSCILLATOR WITH TEMPERATURE COMPENSATION - An oscillator includes a first capacitor electrically connected to a first charging switch and a first discharging switch, a second capacitor electrically connected to a second charging switch and a second discharging switch, a first chopping circuit having a first input electrically connected to the first capacitor and a second input electrically connected to a reference voltage, a second chopping circuit having a first input electrically connected to the second capacitor and a second input electrically connected to the reference voltage, a first comparator having a first input electrically connected to a first and second output of the first chopping circuit, a second comparator having a first input electrically connected to a first and second output of the second chopping circuit, and control circuitry having a first input electrically coupled to an output of the first comparator and a second input electrically connected to an output of the second comparator. | 07-19-2012 |
20120313720 | Runtime Compensated Oscillator - Disclosed is a method for generating an oscillating signal and an oscillator circuit. | 12-13-2012 |
20120319788 | RELAXATION OSCILLATOR WITH LOW POWER CONSUMPTION - A relaxation oscillator for generating oscillator signal includes a ramp voltage generating circuit, a reference voltage generating circuit, a reference voltage switching circuit, and a digital logic circuit. The reference voltage generating circuit generates one or more reference voltages and the ramp voltage generating circuit generates one or more ramp voltages. The ramp voltages are compared with each of the reference voltages by sequentially switching the reference voltages using a reference voltage switching signal generated by the reference voltage switching circuit. The oscillator signal is generated by the digital logic circuit based on the results of the comparisons. | 12-20-2012 |
20120319789 | RELAXATION OSCILLATOR CIRCUIT WITH REDUCED SENSITIVITY OF OSCILLATION FREQUENCY TO COMPARATOR DELAY VARIATION - A relaxation oscillator circuit with reduced sensitivity of oscillation frequency to comparator delay variation includes a first current source that generates charging current, a second current source coupled to the first current source to generate reference voltage, a resistor coupled to the second current source to enable generation of the reference voltage, a capacitor coupled to the first current source that is charged based on the charging current, a comparator responsive to voltage corresponding to the capacitor and the reference voltage to generate output voltage, a peak detector coupled to the capacitor to generate peak voltage, an error detector coupled to the peak detector and the second current source to generate an error based on the peak voltage and the reference voltage, and a controller coupled to the error detector to control one of the charging current, offset voltage input to the comparator, and capacitance of the capacitor. | 12-20-2012 |
20140176250 | Relaxation Oscillator - In an embodiment, a method includes: during a first portion of a cycle of a clock signal generated by an oscillator, pre-charging a first capacitor of a first switched capacitor stage until a first comparator determines that a first node voltage of the first switched capacitor stage is greater than a first reference voltage at a first reference voltage node; applying a second reference voltage to the first reference voltage node; and responsive to a first edge of the clock signal, charging the first capacitor until the first comparator determines that the first node voltage is greater than the second reference voltage at the first reference voltage node. | 06-26-2014 |
20140197897 | PRECISION OSCILLATOR WITH TEMPERATURE COMPENSATION - New and highly stable oscillators are disclosed. Such an oscillator may include a first capacitor electrically connected to a first charging switch and a first discharging switch, a second capacitor electrically connected to a second charging switch and a second discharging switch, a first chopping circuit having a first input electrically connected to the first capacitor and a second input electrically connected to a reference voltage, a second chopping circuit having a first input electrically connected to the second capacitor and a second input electrically connected to the reference voltage, a first comparator having a first input electrically connected to a first and second output of the first chopping circuit, a second comparator having a first input electrically connected to a first and second output of the second chopping circuit, and control circuitry having a first input electrically coupled to an output of the first comparator and a second input electrically connected to an output of the second comparator. | 07-17-2014 |
20150349710 | RC OSCILLATOR BASED ON DELAY-FREE COMPARATOR - Cancelling a delay in a comparator of an RC oscillator configured to generate a clock pulse, including: selectively coupling a plurality of current sources to a first capacitor, a second capacitor, and a resistor, wherein the plurality of current source charge and discharge the first capacitor and the second capacitor, and charge the resistor; charging the first capacitor at a higher rate during a first phase of the clock pulse than a second phase of the clock pulse, and charging the second capacitor at a higher rate during a third phase of the clock pulse than a fourth phase of the clock pulse; and generating the clock pulse by enabling the comparator to compare a voltage on the first or second capacitor with a voltage on the resistor. | 12-03-2015 |
331144000 | Multivibrators | 2 |
20130049875 | RELAXATION OSCILLATOR CIRCUIT INCLUDING TWO CLOCK GENERATOR SUBCIRCUITS HAVING SAME CONFIGURATION OPERATING ALTERNATELY - A control circuit controls first and second clock generator subcircuits so that one subcircuit of the first and second clock generator subcircuits operates for a comparison voltage generating interval, then another subcircuit operates for a clock generating interval, and so that the first and second clock generator subcircuits alternately repeat processes of the comparison voltage generating interval and the clock generating interval. For the comparison voltage generating interval, each of the first and second clock generator subcircuits is controlled to generate a comparison voltage and output the same voltage to an inverted output terminal of a comparator. For the clock generating interval, each of the first and second clock generator subcircuits compares an output voltage from a current-voltage converter circuit with the comparison voltage. | 02-28-2013 |
20140028408 | COMPARATOR AND RELAXATION OSCILLATOR EMPLOYING SAME - A relaxation oscillator has a comparator that includes first through third bias current transistors coupled to a first supply rail. First and second input transistors form a pair of parallel coupled transistors connected to the first bias current transistor. A first current mirror control transistor connects the first input transistor to a second supply rail. A first current mirror output transistor is coupled to the first current mirror control transistor, and connects the second bias current transistor to the second supply rail. A second current mirror control transistor connects the second input transistor to the second supply rail. A second current mirror output transistor is coupled to the second current mirror control transistor, and connects the third bias current transistor to the second supply rail. A transition time reduction transistor, coupled across the third bias current transistor, is coupled to the second bias current transistor, and provides a comparator output. | 01-30-2014 |
331146000 | Blocking oscillators | 1 |
20140028409 | CHOPPER BASED RELAXATION OSCILLATOR - A reference circuit, an oscillator architecture that includes the reference circuit and a method for operating the reference circuit are described. In one embodiment, the reference circuit includes a voltage reference generator configured to generate a reference voltage and a current reference generator configured to generate a reference current based on the reference voltage. The current reference generator includes a level shifter circuit configured to generate intermediate voltages based on the reference voltage, a first current reference circuit configured to generate intermediate currents based on the intermediate voltages, where the intermediate currents are correlated to the reference voltage, and a second current reference circuit configured to combine the intermediate currents to generate the reference current. Other embodiments are also described. | 01-30-2014 |
331150000 | Output supplied to another discharge device circuit | 2 |
20100141348 | LOW-POWER RELAXATION OSCILLATOR AND RFID TAG USING THE SAME - There is provided a low-power relaxation oscillator. The low-power relaxation oscillator may include: a constant current generation unit generating a current having a predetermined magnitude; a current varying unit controlling the current generated from the constant current generation unit according to a clock control signal to output the controlled current; a first controller and a second controller connected in parallel with output terminals of the current varying unit and passing or interrupting the current supplied from the current varying unit; a PMOS charging/discharging unit arranged between an output terminal of the first controller and an output terminal of the second controller; a first comparator and a second comparator connected to both ends of the PMOS charging/discharging unit, respectively, and each outputting a high or low level voltage upon receiving voltage charged in the PMOS charging/discharging unit; and a latch circuit delaying the voltages output from the first and second comparators to output oscillation signals. | 06-10-2010 |
20160094206 | OSCILLATOR CIRCUIT - Provided is a CR oscillator circuit that achieves a small occupied area and good oscillation frequency accuracy while having small current consumption. The CR oscillator circuit includes: a reference voltage circuit configured to switch and output a reference voltage; a first constant current source configured to charge a capacitor; a second constant current source configured to discharge the capacitor; a voltage comparator configured to compare voltages of the reference voltage circuit and the capacitor; and a logic circuit. The logic circuit is configured to switch between the reference voltage circuit and the constant current source simultaneously in response to an output signal of the voltage comparator. | 03-31-2016 |