Patent application number | Description | Published |
20100194994 | Dual Mode DP and HDMI Transmitter - A system and method for dual mode DP and HDMI transmission are provided. Briefly described, one embodiment of a dual mode DP and HDMI transmitter, among others, can be implemented as follows. The dual mode DP and HDMI transmitter comprises a driver circuit controlled by a data signal. The dual mode DP and HDMI transmitter also comprises a control circuit coupled to the driver circuit. The control circuit is configurable to transmit the data signal in a DP mode or a HDMI mode according to a mode signal. One embodiment of a method, among others, comprises: receiving a mode signal; determining whether to configure the dual mode DP and HDMI transmitter for transmitting in a DP mode or an HDMI mode based on the received mode signal; and configuring a dual mode DP and HDMI transmitter in accordance with the determination. | 08-05-2010 |
20100231176 | Battery Charging System and Method - Methods, devices, and systems for charging a battery in a mobile device are provided. For example, in one embodiment, among others, a battery charging system includes a monitoring circuit configured to monitor a battery and generate a sense current. The battery charging system further includes a comparing circuit configured to compare a reference current and the generated sense current. The comparing circuit is further configured to generate a comparison signal. Also, the battery charging system further includes a control circuit configured to control a level of a charging current applied to the battery based on the comparison signal. | 09-16-2010 |
20110302331 | Dual Mode DP and HDMI Transmitter - A system and method for dual mode DP and HDMI transmission are provided. Briefly described, one embodiment of a dual mode DP and HDMI transmitter, among others, can be implemented as follows. The dual mode DP and HDMI transmitter comprises a driver circuit controlled by a data signal. The dual mode DP and HDMI transmitter also comprises a control circuit coupled to the driver circuit. The control circuit is configurable to transmit the data signal in a DP mode or a HDMI mode according to a mode signal. One embodiment of a method, among others, comprises: receiving a mode signal; determining whether to configure the dual mode DP and HDMI transmitter for transmitting in a DP mode or an HDMI mode based on the received mode signal; and configuring a dual mode DP and HDMI transmitter in accordance with the determination. | 12-08-2011 |
20120151099 | Dual Mode DP and HDMI Transmitter - A system and method for dual mode DP and HDMI transmission are provided. Briefly described, one embodiment of a dual mode DP and HDMI transmitter, among others, can be implemented as follows. The dual mode DP and HDMI transmitter comprises a driver circuit controlled by a data signal. The dual mode DP and HDMI transmitter also comprises a control circuit coupled to the driver circuit. The control circuit is configurable to transmit the data signal in a DP mode or a HDMI mode according to a mode signal. One embodiment of a method, among others, comprises: receiving a mode signal; determining whether to configure the dual mode DP and HDMI transmitter for transmitting in a DP mode or an HDMI mode based on the received mode signal; and configuring a dual mode DP and HDMI transmitter in accordance with the determination. | 06-14-2012 |
20120161886 | VOLTAGE CONTROLLED OSCILLATOR - A voltage controlled oscillator including a control signal adjuster and ring-connected delay cells is disclosed. The control signal adjuster receives a first control signal to generate a second control signal boosted from the first control signal when the first control signal is lower than a transistor threshold voltage. The ring-connected delay cells are controlled by the first and second control signals both to generate an oscillation signal. Each of the delay cells has a first set of current generation transistors and a second set of current generation transistors. Each transistor of the first set of current generation transistors has a control terminal receiving the first control signal while each transistor of the second set of current generation transistors has a control terminal receiving the second control signal. The first and second sets of current generation transistors collectively output an oscillation signal with unchanged frequency of associated input signal. | 06-28-2012 |
20120169395 | LEVEL SHIFTER - A level shifter, converting an input signal into an output signal for level shifting, including a leakage blocking circuit having cascaded P-channel transistors and one N-channel transistor. The P-channel transistor at a beginning stage provides a gate for receiving the input signal and a source coupled to a gate of the P-channel transistor at a secondary stage. At intermediate stages, each P-channel transistor provides a source coupled to a gate of the subsequently cascaded P-channel transistor. At a final stage, the P-channel transistor provides a source coupled to a voltage source and a drain coupled to an output terminal of the leakage blocking circuit for the outputting of the output signal. The N-channel transistor has a gate which is coupled to receive the input signal as well, a source coupled to a common voltage, and a drain coupled to the output terminal of the leakage blocking circuit. | 07-05-2012 |
20120217999 | Low Voltage Differential Signal Driving Circuit and Digital Signal Transmitter - A low voltage differential signal (LVDS) driving circuit and a digital signal transmitter with the LVDS driving circuit are provided. The LVDS driving circuit includes a positive differential output terminal and a negative differential output terminal and a transition accelerator. A differential output signal is provided by the positive and negative differential output terminals. When the differential output signal transits from low to high, the transition accelerator couples the positive differential output terminal to a high voltage source and couples the negative differential output terminal to a low voltage source. When the differential output signal transits from high to low, the transition accelerator couples the positive differential output terminal to the low voltage source and couples the positive output terminal to the high voltage source. | 08-30-2012 |
20130064322 | FREQUENCY-CONTROL CIRCUITS AND SIGNAL GENERATION DEVICES USING THE SAME - A signal generation device is provided to generate an output signal with constant frequency. The signal generation device includes a frequency-control circuit and a voltage-controlled delay line. The frequency-control circuit is arranged to charge/discharge a voltage-control node according to a comparison result signal. The voltage-controlled delay line is arranged to generate a control signal according to the comparison result signal and a control voltage of the voltage-control node to control the output signal. A frequency of the control signal is modulated by the voltage-controlled delay line according to the control voltage of the voltage-control node. The comparison result signal is generated according to a difference between a reference voltage and a voltage level of the output signal. | 03-14-2013 |
20130076404 | LOW VOLTAGE DIFFERENTIAL SIGNAL DRIVING CIRCUIT AND ELECTRONIC DEVICE COMPATIBLE WITH WIRED TRANSMISSION - A low voltage differential signal driving circuit including positive and negative differential output terminals, an automatic level selector, an output level detector and a transition accelerator. The positive and negative differential output terminals provide a transmission interface with a differential output signal for transmission of a data signal. The automatic level selector outputs a reference voltage corresponding to the transmission interface. The output level detector generates a low-high (or high-low) transition acceleration control signal based on the data signal, the reference voltage, and VTXP signal at the positive differential output terminal (or VTXN signal at the negative differential output terminal). In accordance with the low-high (or high-low) transition acceleration control signal, the transition accelerator couples the positive (or negative) differential output terminal to a high voltage source and couples the negative (or positive) differential output terminal to a low voltage source to accelerate transition of the differential output signal. | 03-28-2013 |
20130099840 | DUTY ADJUSTMENT CIRCUITS AND SIGNAL GENERATION DEVICES USING THE SAME - A duty adjustment circuit is provided. The duty adjustment circuit is used to adjust a duty cycle of a first driving signal. The duty adjustment circuit includes a filter, a first comparator, and a first duty adjustor. The filter receives a comparison result signal and filters the comparison result signal to generate a duty information signal. The duty information signal indicates a duty cycle of the comparison result signal. The first comparator receives the duty information signal and determines whether a direct-current (DC) level of the duty information signal falls into a predefined voltage range to generate a first adjustment signal. The first duty adjustor receives the first adjustment signal and the first driving signal and adjusts the duty cycle of the first driving signal according to the first adjustment signal. | 04-25-2013 |
20130222020 | FREQUENCY-CONTROL CIRCUITS AND SIGNAL GENERATION DEVICES USING THE SAME - A signal generation device is provided to generate an output signal with constant frequency. The signal generation device includes a frequency-control circuit and a voltage-controlled delay line. The frequency-control circuit includes a pulse generator, generating a reference pulse signal according to a transition of the reference signal and a comparison pulse signal according to a transition of the comparison result signal, to re-shape the reference signal and the comparison result signal into narrow pulses suitable for clocking and resetting flip-flops. | 08-29-2013 |
20130300511 | VOLTAGE CONTROLLED OSCILLATOR - A voltage controlled oscillator generating an oscillation signal according to a first control signal without a silent region. The voltage controlled oscillator includes a control signal adjuster and a plurality of delay cells. The control signal adjuster receives the first control signal and generates a second and a third control signal according to the first control signal. The voltage level of the third control signal is higher than that of the second control signal and the voltage level of the second control signal is higher than that of the first control signal. The plurality of delay cells are ring-connected and controlled by the first, the second, and the third control signals to generate the oscillation signal. Each delay cell includes three sets of current generation transistors. The three sets of current generation transistors are separately controlled by the three different control signals. | 11-14-2013 |
20140203865 | OUTPUT BUFFERS - An output buffer is provided. The output buffer is coupled to a first voltage source providing a first supply voltage and used for generating an output signal at an output terminal according to an input signal. The output buffer includes first and second transistors and a self-bias circuit. The first and second transistors are cascaded between the output terminal and a reference voltage. The self-bias circuit is coupled to the output terminal and the control electrode of the first transistor. When the output buffer does not receive the first supply voltage, the self-bias circuit provides a first bias voltage to the control electrode of the first transistor according to the output signal to decrease voltage differences between the control electrode and the input and output electrodes of the first transistor to be lower than a predetermined voltage. | 07-24-2014 |
20140361835 | Current Mirror - Some embodiments of the system comprise a current mirror with two switches (a first switch and a second switch) and two compensation circuits (a first compensation circuit and a second compensation circuit). In one embodiment, the first compensation circuit adjusts a drain voltage of the second switch based on a drain voltage of the first switch, and the second compensation circuit adjusts a current through the first switch based on the drain voltage of the second switch. | 12-11-2014 |
20150049839 | Common Mode Modulation with Current Compensation - The present disclosure provides systems and methods for compensating channel modulation effects. Some embodiments comprise a differential switching circuit, a common mode modulation circuit, and a current compensation circuit. The current compensation circuit compensates for channel modulation effects. | 02-19-2015 |