Abstract: The present disclosure provides a method for separating a neural crest derived cell from peripheral blood. In the present disclosure, a mononuclear cell is separated from the peripheral blood and then directly cultured, thereby maximizing use of a neural crest stem cell with a differentiation potential to avoid loss of the neural crest stem cell. In the method of the present disclosure, a sample to be separated is derived from the peripheral blood. The method shows less trauma and low cost. Most importantly, compared to extracting the neural crest derived cell from tissues, the neural crest derived cell extracted from the peripheral blood can be used clinically as a type of biomarker.

Abstract: Disclosed is a method for identifying fragile lines in power grid based on electrical betweenness, which comprises the following steps: constructing the power grid into a network diagram, sequentially removing lines in the network diagram, and sorting the electrical betweenness of each line from large to small; constructing a nonlinear model of complex network cascade failure considering overload and weighted edges, and respectively performing two ways of removing lines for sorted electrical betweenness, namely sequentially removing preset proportion lines and sequentially removing all lines until no new lines are removed in the network diagram; obtaining a change of generator-load power before and after each line removal, and evaluating a severity of power grid failure based on the change of generator-load power, thus completing an identification of power grid fragile lines.

Abstract: A low voltage differential driver includes a first driver, a second driver, and an output driver. The output driver is configured to provide an output between a first output node and a second output node, and includes a current source, a first branch, and a second branch. The current source is configured to provide a source current. The current source is connected with a parallel arrangement of the first branch and the second branch. The first switch and the second switch are respectively controlled by a first switch circuit and a second switch circuit which together comprise the first driver. The third switch and the fourth switch are respectively controlled by a third switch circuit and a fourth switch circuit which together comprise the second driver. Each of the first to fourth switch circuits is connected between the upper node and the lower node.

Abstract: Aspects of the present disclosure include methods, systems, and non-transitory computer readable media that perform the steps of transmitting a token to a gateway, receiving a response token including an encrypted message, decrypting the encrypted message using a decryption key associated with the token to generate a decrypted message, validating content of the decrypted message, transmitting a certificate request in response to successfully validating the content of the decrypted message, receiving a certificate in response to the request, validating the certificate against a certification authority, and transmitting encrypted data via a secured connection in response to successfully validating the certificate.

Abstract: A single-inductor, multiple-output, DC-DC converter has regulation circuitry that controls switches to alternately charge at least two capacitors associated with at least two DC output voltages via the single inductor from a DC input port. The regulation circuitry determines whether the DC-DC converter is operating in continuous conduction mode (CCM) or discontinuous conduction mode (DCM). In CCM mode, the regulation circuitry regulates the charging duty cycle for a first output voltage and generates the initial charging duty cycle for regulating each other output voltage by scaling the first output voltage duty cycle. In DCM mode, the regulation circuitry independently regulates the charging duty cycles for each output voltage and stores each duty cycle to be used for the next charging period for the same output voltage. The regulation circuitry detects and handles undershoot and overshoot conditions to accelerate recovery at the output ports.

Abstract: A low voltage differential driver includes a first driver, a second driver, and an output driver. The output driver is configured to provide an output between a first output node and a second output node, and includes a current source, a first branch, and a second branch. The current source is configured to provide a source current. The current source is connected with a parallel arrangement of the first branch and the second branch connected between an upper node and a lower node. The first branch includes a first switch, a second switch, and the first output node therebetween. The second branch is connected in parallel with the first branch, and includes a third switch, a fourth switch, and the second output node. The first switch and the second switch are respectively controlled by a first switch circuit and a second switch circuit which together comprise the first driver.

Abstract: Aspects of the present disclosure include methods, systems, and non-transitory computer readable media that perform the steps of transmitting a token to a gateway, receiving a response token including an encrypted message, decrypting the encrypted message using a decryption key associated with the token to generate a decrypted message, validating content of the decrypted message, transmitting a certificate request in response to successfully validating the content of the decrypted message, receiving a certificate in response to the request, validating the certificate against a certification authority, and transmitting encrypted data via a secured connection in response to successfully validating the certificate.

Abstract: A single-inductor, multiple-output, DC-DC converter has regulation circuitry that controls switches to alternately charge at least two capacitors associated with at least two DC output voltages via the single inductor from a DC input port. The regulation circuitry determines whether the DC-DC converter is operating in continuous conduction mode (CCM) or discontinuous conduction mode (DCM). In CCM mode, the regulation circuitry regulates the charging duty cycle for a first output voltage and generates the initial charging duty cycle for regulating each other output voltage by scaling the first output voltage duty cycle. In DCM mode, the regulation circuitry independently regulates the charging duty cycles for each output voltage and stores each duty cycle to be used for the next charging period for the same output voltage. The regulation circuitry detects and handles undershoot and overshoot conditions to accelerate recovery at the output ports.

Abstract: Embodiments provide a chip and a related device. In those embodiments, the chip includes a ring network. The ring network includes a first node and a second a node. The first node determines whether a first injection buffer value is greater than a first threshold and whether a first injection bandwidth is less than a first expected bandwidth. When the first injection buffer value is greater than the first threshold and the first injection bandwidth is less than the first expected bandwidth, the first node sends a first request to the second node, where the first request is used to instruct at least one node in the ring network, other than the first node, to reduce a transmission quantity of first data packets. According to the embodiments of this application, a network bandwidth can be properly allocated according to an actual operating status of a system.

Abstract: A single-inductor DC-DC converter generates two DC output voltages at two capacitors. The converter selectively transfers energy from a battery to the inductor or from the inductor to a selected capacitor. While the converter is still settling, the converter is regulated based on only the more deficient DC output voltage. After the converter has already settled, the converter is regulated based on the common-mode voltage for both DC output voltages. By regulating the still-settling converter based on only the more deficient DC output voltage, instead of the common-mode voltage, even greater deficiencies in that already more-deficient DC output voltage are avoided.

Abstract: One example discloses A differential receiver, including: a set of high voltage differential inputs configured to receive a first range of differential voltages; a first level shifter configured to generate a second range of differential voltages that are less than the first range of differential voltages; and a first low voltage differential comparator coupled to the first level shifter and configured to generate a first differential receiver output based on the second range of differential voltages.

Abstract: A DC-DC power converter converts a DC input voltage at an input node into a DC output voltage at an output node. The converter has a main control loop that generates control signals used to control series-connected p-type and n-type switches that selectively connect an inductor to the input node or to ground while operating the converter in either a continuous-conduction mode (CCM) or a discontinuous-conduction mode (DCM). Zero-crossing detection (ZCD) circuitry detects when the inductor current reaches zero and generates a ZCD control signal used to control the n-type switch to inhibit negative inductor currents during the DCM mode. Overshoot-protection (OP) circuitry detects when the DC output voltage gets too high and generates an OP control signal used to control the n-type switch to inhibit overshoot conditions at the output node that can result from CCM-to-DCM mode transitions and from sudden reductions in output current loading.

Abstract: One example discloses A differential receiver, including: a set of high voltage differential inputs configured to receive a first range of differential voltages; a first level shifter configured to generate a second range of differential voltages that are less than the first range of differential voltages; and a first low voltage differential comparator coupled to the first level shifter and configured to generate a first differential receiver output based on the second range of differential voltages.

Abstract: A single-inductor DC-DC converter generates two DC output voltages at two capacitors. The converter selectively transfers energy from a battery to the inductor or from the inductor to a selected capacitor. While the converter is still settling, the converter is regulated based on only the more deficient DC output voltage. After the converter has already settled, the converter is regulated based on the common-mode voltage for both DC output voltages. By regulating the still-settling converter based on only the more deficient DC output voltage, instead of the common-mode voltage, even greater deficiencies in that already more-deficient DC output voltage are avoided.

Abstract: A level shifter in a primary voltage domain has a control module receiving an input signal from a secondary voltage domain for controlling operation of the level shifter. The control module includes a complementary pair of transistors and a first native transistor connected in a series current conduction path in the primary voltage domain. The complementary pair of transistors have gates connected to receive the input signal and the first native transistor has a gate connected to limit to a leakage current the current in the series current conduction path.

Abstract: In various embodiments, a dynamic range converter includes a plurality of circuits, including at least one configurable circuit that operates based on configuration data. The plurality of circuits include a first color space converter to convert a source color space of a source video having a source dynamic range to nonlinear color space signals. A linearizer configured converts the nonlinear color space signals to linearized color space signals having a mastering dynamic range via a piecewise linear interpolation of a transfer function. A color volume transformer applies dynamic color transform metadata associated with the source video to generate master adjusted color space signals from the linearized color space signals. A delinearizer converts the master adjusted color space signals to nonlinearized color space signals via a piecewise linear interpolation of an inverse transfer function in accordance with a display dynamic range.

Abstract: In various embodiments, a dynamic range converter includes a first color space converter to convert a source color space of a source video having a source dynamic range to nonlinear color space signals. A linearizer configured converts the nonlinear color space signals to linearized color space signals having a mastering dynamic range via a piecewise linear interpolation of a transfer function. A color volume transformer applies dynamic color transform metadata associated with the source video on a frame by frame basis to generate master adjusted color space signals from the linearized color space signals. A delinearizer converts the master adjusted color space signals to nonlinearized color space signals via a piecewise linear interpolation of an inverse transfer function in accordance with a display dynamic range. A second color space converter converts the nonlinearized color space signals to display domain signals. Other embodiments are disclosed.

Abstract: In various embodiments, a dynamic range converter includes a first color space converter to convert a source color space of a source video having a source dynamic range to nonlinear color space signals. A linearizer configured converts the nonlinear color space signals to linearized color space signals having a mastering dynamic range via a piecewise linear interpolation of a transfer function. A color volume transformer applies dynamic color transform metadata associated with the source video to generate master adjusted color space signals from the linearized color space signals. A delinearizer converts the master adjusted color space signals to nonlinearized color space signals via a piecewise linear interpolation of an inverse transfer function in accordance with a display dynamic range. A second color space converter converts the nonlinearized color space signals to display domain signals. Other embodiments are disclosed.

Abstract: A level shifter in a primary voltage domain has a control module receiving an input signal from a secondary voltage domain for controlling operation of the level shifter. The control module includes a complementary pair of transistors and a first native transistor connected in a series current conduction path in the primary voltage domain. The complementary pair of transistors have gates connected to receive the input signal and the first native transistor has a gate connected to limit to a leakage current the current in the series current conduction path.

Abstract: In various embodiments, a dynamic range converter includes a first color space converter to convert a source color space of a source video having a source dynamic range to nonlinear color space signals. A linearizer configured converts the nonlinear color space signals to linearized color space signals having a mastering dynamic range via a piecewise linear interpolation of a transfer function. A color volume transformer applies dynamic color transform metadata associated with the source video on a frame by frame basis to generate master adjusted color space signals from the linearized color space signals. A delinearizer converts the master adjusted color space signals to nonlinearized color space signals via a piecewise linear interpolation of an inverse transfer function in accordance with a display dynamic range. A second color space converter converts the nonlinearized color space signals to display domain signals. Other embodiments are disclosed.