Abstract: The disclosure can be applicable to the field of displaying technologies and provide a method for controlling a displaying direction, and a mobile terminal. The disclosure may monitor an adjustment event for a displaying direction of a focus window, determine the displaying direction of the focus window based on the adjustment event in response to monitoring the adjustment event, and adjust a displaying direction of an underlying application corresponding to the focus window based on the displaying direction of the focus window.

Abstract: A method for displaying an application program, a terminal device, and a storage medium which are applied to intelligent terminals. The method includes: determining whether an application program to be currently started is displayed by means of a Freeform window; if the application program to be currently started is displayed by means of a Freeform window, acquiring a display interface specified by the application program and corresponding to a work task; and after the application program is started, displaying the acquired specified display interface corresponding to the work task in a Freeform window as a display interface of the application program.

Abstract: A window adjustment method, a window adjustment device, a mobile terminal and a computer readable storage medium. The window adjustment method comprises: detecting the number of free windows displayed by a mobile terminal (101); if the number of the windows is not less than two, determining a free window to be adjusted among the free windows displayed by the mobile terminal (102); acquiring an adjustment parameter, and adjusting, on the basis of the adjustment parameter, the free window to be adjusted (103), the adjustment parameter comprising a positional parameter and/or a size parameter. The method allows a user to adjust a window according to his/her needs, so as to avoid the window being blocked and affecting the use thereof by the user.

Abstract: Disclosed are a window switching method, a terminal and a non-transitory computer-readable storage medium. The method comprises: determining whether an application program running at a foreground of a terminal is displayed in the manner of a free window Freeform; if the application program is displayed in the manner of a free window Freeform, monitoring whether a trigger event satisfying a pre-set condition occurs at the free window Freeform; and if it is monitored that the trigger event satisfying the pre-set condition occurs at the free window Freeform, switching the free window Freeform to a full-screen display window.

Abstract: A window adjustment method is provided and includes operations of: when an application program in a mobile terminal being displayed in the form of a free window, monitoring touch-control information on a display interface of the mobile terminal; if the monitored touch-control information is sliding information of two touch points, determining a free window corresponding to the touch-control information, and determining an angle between the sliding directions of the two touch points; and based on the angle between the sliding directions of the two touch points, zooming or moving the free window corresponding to the touch-control information.

Abstract: The embodiments of the disclosure provide a method for displaying an input method interface, a device, a terminal and a storage medium, relating to the field of human-computer interaction technologies. The method includes: displaying a first user interface of a first application; displaying a first floating window on the first user interface, the first floating window being configured for displaying a second user interface of a second application; and displaying a second floating window on the first user interface when a text input operation signal from the second user interface is received, wherein the first floating window and the second floating window are displayed concurrently, and the second floating window is configured for displaying an input method interface.

Abstract: A downstream data frame transmitting method includes: generating, by an optical line terminal (OLT), a downstream data frame, where the downstream data frame includes a frame header and a payload, the frame header includes a physical synchronization sequence (Psync) field, and the Psync field is used to identify the downstream data frame, where when a value of the Psync field is a first value, the Psync field is further used to indicate that payload data is protected by forward error correction (FEC); or when a value of the Psync field is a second value, the Psync field is further used to indicate that payload data is not protected by FEC; and sending, by the OLT, the downstream data frame. Embodiments of the present invention can reduce a bit error rate of a FEC indication status and improve reliability of the FEC indication status.

Abstract: Embodiments of the present invention disclose an EPON communication method, an ONU, and an OLT. The method includes: generating, by an ONU, a first control frame, where the first control frame includes a first data field, and the first data field includes a bandwidth requirement of the at least one LLID; and sending, by the ONU, the first control frame to an OLT. In addition, the OLT generates a second control frame, where the second control frame includes a second data field, and the second data field includes grant information of the at least one LLID; and the OLT sends the second control frame to the ONU. In the embodiments of the present invention, the first control frame may carry bandwidth requirements of a plurality of LLIDs, so that one first control frame can be used to report bandwidth requirements of a plurality of LLIDs.

Abstract: A data encoding method and apparatus and a data decoding method and apparatus in a passive optical network (PON) system include collecting N data blocks at a physical coding sublayer and generating valid data by combining the N data blocks, generating a payload, where the payload includes the valid data, performing FEC encoding on the payload to generate a check part, and generating a codeword structure. The synchronization header may be located at the head or the tail of the codeword structure.

Abstract: Provided is a method for controlling smooth switching of an operation direction of a bidirectional resonant CLLC circuit, which applies to the bidirectional resonant CLLC circuit. The method includes the following steps: Step 1: detecting a current circuit state and controlling the bidirectional resonant CLLC circuit to operate in a forward operation state by means of a primary bridge and a secondary bridge, by a controller; Step 2: performing Step 3 when an externally transmitted reference signal received by the controller or an internal preset reference signal in the controller is an operation direction switching signal; Step 3: performing frequency conversion control, by the controller; Step 4: performing preparation of phase shift control and generating a driving signal of the secondary bridge, by the controller; Step 5: performing the phase shift control, by the controller; and Step 6: switching a circuit operation state to an inverse operation mode.

Abstract: Embodiments of the disclosure relate to methods and a system for adjusting the chucking voltage of an electrostatic chuck. In one embodiment, a system for plasma processing a substrate includes a plasma processing chamber, a radio-frequency (RF) matching circuit coupled to the chamber, a sensor and a controller. The chamber includes a chamber body having an inner volume, a bipolar electrostatic chuck disposed in the inner volume and a power supply configured to provide chucking voltage to a pair of electrodes embedded within the electrostatic chuck. When plasma is energized within the chamber by the application of RF power through an RF matching circuit, the sensor is configured to detect a change in an electrical characteristic at the RF matching circuit. The controller is coupled to the power supply and configured to adjust the chucking voltage in response to the change in the electrical characteristic detected by the sensor.

Abstract: Methods for modulating local stress and overlay error of one or more patterning films may include modulating a gas flow profile of gases introduced into a chamber body, flowing gases within the chamber body toward a substrate, rotating the substrate, and unifying a center-to-edge temperature profile of the substrate by controlling the substrate temperature with a dual zone heater. A chamber for depositing a film may include a chamber body comprising one or more processing regions. The chamber body may include a gas distribution assembly having a blocker plate for delivering gases into the one or more processing regions. The blocker plate may have a first region and a second region, and the first region and second region each may have a plurality of holes. The chamber body may have a dual zone heater.

Abstract: Embodiments of the present invention disclose an EPON communication method, an ONU, and an OLT. The method includes: generating, by an ONU, a first control frame, where the first control frame includes a first data field, and the first data field includes a bandwidth requirement of the at least one LLID; and sending, by the ONU, the first control frame to an OLT. In addition, the OLT generates a second control frame, where the second control frame includes a second data field, and the second data field includes grant information of the at least one LLID; and the OLT sends the second control frame to the ONU. In the embodiments of the present invention, the first control frame may carry bandwidth requirements of a plurality of LLIDs, so that one first control frame can be used to report bandwidth requirements of a plurality of LLIDs.

Abstract: Embodiments of the present invention provide a downstream data frame transmitting method. The method includes: generating, by an OLT, a downstream data frame, where the downstream data frame includes a frame header and a payload, the frame header includes a physical synchronization sequence (Psync) field, and the Psync field is used to identify the downstream data frame, where when a value of the Psync field is a first value, the Psync field is further used to indicate that payload data is protected by forward error correction (FEC); or when a value of the Psync field is a second value, the Psync field is further used to indicate that payload data is not protected by FEC; and sending, by the OLT, the downstream data frame. The embodiments of the present invention can reduce a bit error rate of a FEC indication status and improve reliability of the FEC indication status.

Abstract: Embodiments of the disclosure relate to methods and a system for adjusting the chucking voltage of an electrostatic chuck. In one embodiment, a system for plasma processing a substrate includes a plasma processing chamber, a radio-frequency (RF) matching circuit coupled to the chamber, a sensor and a controller. The chamber includes a chamber body having an inner volume, a bipolar electrostatic chuck disposed in the inner volume and a power supply configured to provide chucking voltage to a pair of electrodes embedded within the electrostatic chuck. When plasma is energized within the chamber by the application of RF power through an RF matching circuit, the sensor is configured to detect a change in an electrical characteristic at the RF matching circuit. The controller is coupled to the power supply and configured to adjust the chucking voltage in response to the change in the electrical characteristic detected by the sensor.

Abstract: Embodiments described herein relate to a faceplate for improving film uniformity. A semiconductor processing apparatus includes a pedestal, an edge ring and a faceplate having distinct regions with differing hole densities. The faceplate has an inner region and an outer region which surrounds the inner region. The inner region has a greater density of holes formed therethrough when compared to the outer region. The inner region is sized to correspond with a substrate being processed while the outer region is sized to correspond with the edge ring.

Abstract: An optical network system comprising an optical line terminal (OLT) and an optical network unit (ONU) coupled to the OLT and configured to communicate with the OLT via an optical signal. At least one of the OLT or the ONU comprises a closed-loop gain controlled transimpedance amplifier (TIA) comprising a first amplifier configured to receive an input signal, generate a main output signal by amplifying the input signal according to a gain factor of the first amplifier, and generate an auxiliary output proportional to the input signal, an average detector coupled to the first amplifier and configured to receive the auxiliary output, and determine an average of the input signal according to the auxiliary output, and a feedback loop coupled to the first amplifier and the average detector and configured to control the gain factor of the first amplifier according to the average of the input signal.

Abstract: An optical network system comprising an optical line terminal (OLT) and an optical network unit (ONU) coupled to the OLT and configured to communicate with the OLT via an optical signal. At least one of the OLT or the ONU comprises a closed-loop gain controlled transimpedance amplifier (TIA) comprising a first amplifier configured to receive an input signal, generate a main output signal by amplifying the input signal according to a gain factor of the first amplifier, and generate an auxiliary output proportional to the input signal, an average detector coupled to the first amplifier and configured to receive the auxiliary output, and determine an average of the input signal according to the auxiliary output, and a feedback loop coupled to the first amplifier and the average detector and configured to control the gain factor of the first amplifier according to the average of the input signal.

Abstract: Methods for modulating local stress and overlay error of one or more patterning films may include modulating a gas flow profile of gases introduced into a chamber body, flowing gases within the chamber body toward a substrate, rotating the substrate, and unifying a center-to-edge temperature profile of the substrate by controlling the substrate temperature with a dual zone heater. A chamber for depositing a film may include a chamber body comprising one or more processing regions. The chamber body may include a gas distribution assembly having a blocker plate for delivering gases into the one or more processing regions. The blocker plate may have a first region and a second region, and the first region and second region each may have a plurality of holes. The chamber body may have a dual zone heater.

Abstract: Methods for modulating local stress and overlay error of one or more patterning films may include modulating a gas flow profile of gases introduced into a chamber body, flowing gases within the chamber body toward a substrate, rotating the substrate, and unifying a center-to-edge temperature profile of the substrate by controlling the substrate temperature with a dual zone heater. A chamber for depositing a film may include a chamber body comprising one or more processing regions. The chamber body may include a gas distribution assembly having a blocker plate for delivering gases into the one or more processing regions. The blocker plate may have a first region and a second region, and the first region and second region each may have a plurality of holes. The chamber body may have a dual zone heater.