Patents by Inventor Michael Y. Zhang
Michael Y. Zhang has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).
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Patent number: 11588517Abstract: Signal correction circuitry is described that improves the integrity of data transmitted over a serial data interface without interrupting the communication between the connected devices. The signal correction circuitry includes edge correction circuitry that speeds up the rising and falling edges of the data signal(s). The signal correction circuitry also includes DC compensation circuitry that boosts the level(s) of the data signal(s).Type: GrantFiled: January 25, 2021Date of Patent: February 21, 2023Assignee: Diodes IncorporatedInventors: ZhangQi Jason Guo, Xin Mao, Michael Y. Zhang
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Publication number: 20220239334Abstract: Signal correction circuitry is described that improves the integrity of data transmitted over a serial data interface without interrupting the communication between the connected devices. The signal correction circuitry includes edge correction circuitry that speeds up the rising and falling edges of the data signal(s). The signal correction circuitry also includes DC compensation circuitry that boosts the level(s) of the data signal(s).Type: ApplicationFiled: January 25, 2021Publication date: July 28, 2022Inventors: ZhangQi Jason Guo, Xin Mao, Michael Y. Zhang
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Patent number: 9762287Abstract: Multiplexers are described in which differential signals on the signal paths associated with unselected differential inputs are converted to common mode signals to reduce crosstalk between unselected signal paths and the multiplexer's active signal path.Type: GrantFiled: June 1, 2015Date of Patent: September 12, 2017Assignee: Pericom Semiconductor CorporationInventors: Tony Yeung, Michael Y. Zhang
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Patent number: 9552322Abstract: Hybrid repeaters are described that are capable of transmitting data in accordance with different versions of a serial data protocol are described. The appropriate circuitry to be used to transmit incoming serial data is determined by monitoring sideband communication (e.g., a link training handshake) between the transmitter and the receiver.Type: GrantFiled: June 12, 2014Date of Patent: January 24, 2017Assignee: Pericom Semiconductor CorporationInventors: Tony Yeung, Michael Y. Zhang
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Publication number: 20160352387Abstract: Multiplexers are described in which differential signals on the signal paths associated with unselected differential inputs are converted to common mode signals to reduce crosstalk between unselected signal paths and the multiplexer's active signal path.Type: ApplicationFiled: June 1, 2015Publication date: December 1, 2016Inventors: Tony Yeung, Michael Y. Zhang
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Patent number: 9391523Abstract: Methods and apparatuses are disclosed for generating a temperature independent current limit. The value of the temperature independent current limit may be determined based in part on an error signal representative of a difference between an actual output value and a desired output value of a power converter. When the error signal is below a lower threshold voltage, the temperature independent current limit may be set to a first value. When the error signal is above an upper threshold voltage, the temperature independent current limit may be set to a second, higher value. When the error signal is between the lower threshold voltage and the upper threshold voltage, the temperature independent current limit may change linearly with the error signal. The error signal may be adjusted to compensate for changes in the system caused by a change in temperature.Type: GrantFiled: September 23, 2011Date of Patent: July 12, 2016Assignee: Power Integrations, Inc.Inventors: Yury Gaknoki, Mingming Mao, Michael Y. Zhang
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Patent number: 9261550Abstract: An in-situ unplug detector circuit detects when a cable is disconnected or unplugged. Detection does not have to wait for normal signaling to pause, such at the end of a frame or timeout. Instead, detection occurs during normal signaling. When the cable is disconnected, the transmitter no longer drives the load at the far end of the cable, and thus can drive the near end to a higher high voltage and to a lower low voltage. The increased voltage swing is detected by a detector at the near end that amplifies the transmitter output to the cable. A fast detector has a higher bandwidth and faster response time than a slow detector, and generates a fast detect signal that crosses over a slow detect signal. When the cable is disconnected, the fast detect signal again crosses over the slow detect signal, and decision logic activates an unplug signal.Type: GrantFiled: June 17, 2014Date of Patent: February 16, 2016Assignee: Pericom Semiconductor CorporationInventors: Hung-Yan Cheung, Michael Y. Zhang
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Patent number: 9264102Abstract: Distortions of both amplitude and phase along a transmission line are compensated for by a trace canceller inserted between a transmitter and a receiver. The trace canceller has an equalizer that compensates for a trace length between the transmitter and the trace canceller. A variable gain amplifier between the equalizer and an output buffer has its gain controlled by an automatic gain control circuit that compares low-frequency swings of the input and output of the trace canceller. The gain of the variable gain amplifier is reduced to prevent the output buffer from saturating and clipping peak voltages on its output. Thus both the variable gain amplifier and the output buffer remain in the linear region. Training pulses from the transmitter are passed through the trace canceller without clipping of peak voltages, allowing the transmitter and receiver to adjust transmission parameters to best match the transmission line.Type: GrantFiled: July 7, 2015Date of Patent: February 16, 2016Assignee: Pericom Semiconductor CorporationInventors: Hung-Yan Cheung, Michael Y. Zhang
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Publication number: 20150363350Abstract: Hybrid repeaters are described that are capable of transmitting data in accordance with different versions of a serial data protocol are described. The appropriate circuitry to be used to transmit incoming serial data is determined by monitoring sideband communication (e.g., a link training handshake) between the transmitter and the receiver.Type: ApplicationFiled: June 12, 2014Publication date: December 17, 2015Inventors: Tony Yeung, Michael Y. Zhang
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Publication number: 20150311950Abstract: Distortions of both amplitude and phase along a transmission line are compensated for by a trace canceller inserted between a transmitter and a receiver. The trace canceller has an equalizer that compensates for a trace length between the transmitter and the trace canceller. A variable gain amplifier between the equalizer and an output buffer has its gain controlled by an automatic gain control circuit that compares low-frequency swings of the input and output of the trace canceller. The gain of the variable gain amplifier is reduced to prevent the output buffer from saturating and clipping peak voltages on its output. Thus both the variable gain amplifier and the output buffer remain in the linear region. Training pulses from the transmitter are passed through the trace canceller without clipping of peak voltages, allowing the transmitter and receiver to adjust transmission parameters to best match the transmission line.Type: ApplicationFiled: July 7, 2015Publication date: October 29, 2015Inventors: Hung-Yan Cheung, Michael Y. Zhang
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Patent number: 9106464Abstract: Distortions of both amplitude and phase along a transmission line are compensated for by a trace canceller inserted between a transmitter and a receiver. The trace canceller has an equalizer that compensates for a trace length between the transmitter and the trace canceller. A variable gain amplifier between the equalizer and an output buffer has its gain controlled by an automatic gain control circuit that compares low-frequency swings of the input and output of the trace canceller. The gain of the variable gain amplifier is reduced to prevent the output buffer from saturating and clipping peak voltages on its output. Thus both the variable gain amplifier and the output buffer remain in the linear region. Training pulses from the transmitter are passed through the trace canceller without clipping of peak voltages, allowing the transmitter and receiver to adjust transmission parameters to best match the transmission line.Type: GrantFiled: January 28, 2014Date of Patent: August 11, 2015Assignee: Pericom Semiconductor Corp.Inventors: Hung-Yan Cheung, Michael Y. Zhang
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Patent number: 9094245Abstract: A redriver chip is inserted between a transmitter chip and a receiver chip and re-drives differential signals from the transmitter chip to the receiver chip. The redriver chip has switched output termination that switches to a high value to detect far-end termination at the receiver chip, and to a low value for signaling. An output detector detects when the receiver chip has termination to ground and enables switched input termination to provide termination to ground on the lines back to the transmitter chip so that the far-end termination on the receiver chip is mirrored back to the transmitter chip, hiding the redriver chip. An input signal detector detects when the transmitter chip begins signaling and enables an equalizer, limiter, pre-driver, and output stage to re-drive the signals to the receiver chip. The input signal detector also causes the switched output termination to switch to the low value termination for signaling.Type: GrantFiled: November 14, 2013Date of Patent: July 28, 2015Assignee: Pericom Semiconductor CorporationInventors: Tony Yeung, Michael Y. Zhang
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Publication number: 20150002167Abstract: An in-situ unplug detector circuit detects when a cable is disconnected or unplugged. Detection does not have to wait for normal signaling to pause, such at the end of a frame or timeout. Instead, detection occurs during normal signaling. When the cable is disconnected, the transmitter no longer drives the load at the far end of the cable, and thus can drive the near end to a higher high voltage and to a lower low voltage. The increased voltage swing is detected by a detector at the near end that amplifies the transmitter output to the cable. A fast detector has a higher bandwidth and faster response time than a slow detector, and generates a fast detect signal that crosses over a slow detect signal. When the cable is disconnected, the fast detect signal again crosses over the slow detect signal, and decision logic activates an unplug signal.Type: ApplicationFiled: June 17, 2014Publication date: January 1, 2015Inventors: Hung-Yan Cheung, Michael Y. Zhang
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Publication number: 20140210509Abstract: A redriver chip is inserted between a transmitter chip and a receiver chip and re-drives differential signals from the transmitter chip to the receiver chip. The redriver chip has switched output termination that switches to a high value to detect far-end termination at the receiver chip, and to a low value for signaling. An output detector detects when the receiver chip has termination to ground and enables switched input termination to provide termination to ground on the lines back to the transmitter chip so that the far-end termination on the receiver chip is mirrored back to the transmitter chip, hiding the redriver chip. An input signal detector detects when the transmitter chip begins signaling and enables an equalizer, limiter, pre-driver, and output stage to re-drive the signals to the receiver chip. The input signal detector also causes the switched output termination to switch to the low value termination for signaling.Type: ApplicationFiled: November 14, 2013Publication date: July 31, 2014Applicant: Pericom Semiconductor CorporationInventors: Tony Yeung, Michael Y. Zhang
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Patent number: 8786291Abstract: An in-situ unplug detector circuit detects when a cable is disconnected or unplugged. Detection does not have to wait for normal signaling to pause, such at the end of a frame or timeout. Instead, detection occurs during normal signaling. When the cable is disconnected, the transmitter no longer drives the load at the far end of the cable, and thus can drive the near end to a higher high voltage and to a lower low voltage. The increased voltage swing is detected by a detector at the near end that amplifies the transmitter output to the cable. A fast detector has a higher bandwidth and faster response time than a slow detector, and generates a fast detect signal that crosses over a slow detect signal. When the cable is disconnected, the fast detect signal again crosses over the slow detect signal, and decision logic activates an unplug signal.Type: GrantFiled: August 25, 2011Date of Patent: July 22, 2014Assignee: Pericom Semiconductor CorporationInventors: Hung-Yan Cheung, Michael Y. Zhang
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Publication number: 20140140386Abstract: Distortions of both amplitude and phase along a transmission line are compensated for by a trace canceller inserted between a transmitter and a receiver. The trace canceller has an equalizer that compensates for a trace length between the transmitter and the trace canceller. A variable gain amplifier between the equalizer and an output buffer has its gain controlled by an automatic gain control circuit that compares low-frequency swings of the input and output of the trace canceller. The gain of the variable gain amplifier is reduced to prevent the output buffer from saturating and clipping peak voltages on its output. Thus both the variable gain amplifier and the output buffer remain in the linear region. Training pulses from the transmitter are passed through the trace canceller without clipping of peak voltages, allowing the transmitter and receiver to adjust transmission parameters to best match the transmission line.Type: ApplicationFiled: January 28, 2014Publication date: May 22, 2014Applicant: Pericom Semiconductor CorporationInventors: Hung-Yan Cheung, Michael Y. Zhang
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Patent number: 8675714Abstract: Distortions of both amplitude and phase along a transmission line are compensated for by a trace canceller inserted between a transmitter and a receiver. The trace canceller has an equalizer that compensates for a trace length between the transmitter and the trace canceller. A variable gain amplifier between the equalizer and an output buffer has its gain controlled by an automatic gain control circuit that compares low-frequency swings of the input and output of the trace canceller. The gain of the variable gain amplifier is reduced to prevent the output buffer from saturating and clipping peak voltages on its output. Thus both the variable gain amplifier and the output buffer remain in the linear region. Training pulses from the transmitter are passed through the trace canceller without clipping of peak voltages, allowing the transmitter and receiver to adjust transmission parameters to best match the transmission line.Type: GrantFiled: October 12, 2010Date of Patent: March 18, 2014Assignee: Pericom Semiconductor CorporationInventors: Hung-Yan Cheung, Michael Y. Zhang
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Patent number: 8610463Abstract: A redriver chip is inserted between a transmitter chip and a receiver chip and re-drives differential signals from the transmitter chip to the receiver chip. The redriver chip has switched output termination that switches to a high value to detect far-end termination at the receiver chip, and to a low value for signaling. An output detector detects when the receiver chip has termination to ground and enables switched input termination to provide termination to ground on the lines back to the transmitter chip so that the far-end termination on the receiver chip is mirrored back to the transmitter chip, hiding the redriver chip. An input signal detector detects when the transmitter chip begins signaling and enables an equalizer, limiter, pre-driver, and output stage to re-drive the signals to the receiver chip. The input signal detector also causes the switched output termination to switch to the low value termination for signaling.Type: GrantFiled: June 1, 2012Date of Patent: December 17, 2013Assignee: Pericom Semiconductor Corp.Inventors: Tony Yeung, Michael Y. Zhang
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Publication number: 20130159759Abstract: Embodiments of an apparatus for signal conditioning, a serial data interface, and a method for a programmable delay filter are disclosed. In an embodiment of an apparatus for signal conditioning, a wave shaping circuit has a precursor signal, a post cursor signal, and a main signal combined to provide an output signal. The precursor signal, the post cursor signal, and the main signal are provided for combination independently of a clock signal. The main signal is delayed relative to the precursor signal, and the post cursor signal is delayed relative to the main signal.Type: ApplicationFiled: December 14, 2011Publication date: June 20, 2013Inventors: Tony Yeung, Michael Y. Zhang
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Publication number: 20130077358Abstract: Methods and apparatuses are disclosed for generating a temperature independent current limit. The value of the temperature independent current limit may be determined based in part on an error signal representative of a difference between an actual output value and a desired output value of a power converter. When the error signal is below a lower threshold voltage, the temperature independent current limit may be set to a first value. When the error signal is above an upper threshold voltage, the temperature independent current limit may be set to a second, higher value. When the error signal is between the lower threshold voltage and the upper threshold voltage, the temperature independent current limit may change linearly with the error signal. The error signal may be adjusted to compensate for changes in the system caused by a change in temperature.Type: ApplicationFiled: September 23, 2011Publication date: March 28, 2013Applicant: Power Integrations, Inc.Inventors: Yury Gaknoki, Mingming Mao, Michael Y. Zhang