Abstract: A multiple-input and multiple-output (MIMO) bolt-on device for a single-input and single-output (SISO) radio, a MIMO channel emulator for testing the MIMO bolt-on device, and a MIMO channel emulation method are provided. The MIMO bolt-on device includes: a plurality of antennas, a multi-channel receiver, a plurality of couplers, a micro-controller, and a switch device. The multi-channel receiver includes a plurality of channels for signal transmission. Each coupler is configured to couple the multi-channel receiver with one of the plurality of antennas. The micro-controller is coupled to the multi-channel receiver to compare signals from the plurality of channels, thereby identifying a channel with a highest signal-to-noise (SNR) among the plurality of channels. The switch device is coupled to the micro-controller and configured to select an antenna corresponding to the channel with the highest SNR among the plurality of antennas for a connection between a selected antenna and the SISO radio.

Abstract: Techniques described herein may be used to conserver battery power of an Internet of Things (IoT) tracker by increasing the overall amount of time that the IoT tracker is in a battery conservation mode (a sleep mode, a Power Save Mode (PSM), etc.). An IoT tracker may implement a battery conservation policy that may include instructions that cause the IoT tracker to monitor certain conditions, determine when the conditions satisfy a particular trigger, and implement a battery conservation mode in response to those conditions. Examples of such conditions may include (1) the IoT tracker being close to a user device designated to track the location of the IoT tracker, (2) identifying that a current time and day are associated with a pre-selected schedule for disabling tracking services, (3) the IoT tracker being located within a particular geographic area, and more.

Abstract: A multiple-input and multiple-output (MIMO) bolt-on device for a single-input and single-output (SISO) radio, a MIMO channel emulator for testing the MIMO bolt-on device, and a MIMO channel emulation method are provided. The MIMO bolt-on device includes: a plurality of antennas, a multi-channel receiver, a plurality of couplers, a micro-controller, and a switch device. The multi-channel receiver includes a plurality of channels for signal transmission. Each coupler is configured to couple the multi-channel receiver with one of the plurality of antennas. The micro-controller is coupled to the multi-channel receiver to compare signals from the plurality of channels, thereby identifying a channel with a highest signal-to-noise (SNR) among the plurality of channels. The switch device is coupled to the micro-controller and configured to select an antenna corresponding to the channel with the highest SNR among the plurality of antennas for a connection between a selected antenna and the SISO radio.

Abstract: An email attempting to perpetrate a business email compromise (BEC) attack is detected based on similarity of the email to a known BEC email and on similarity of the email to a user email that would have been sent by the purported sender of the email. Metadata of the email is extracted and input to a BEC machine learning model to find the known BEC email among BEC email samples. The extracted metadata are also input to a personal user machine learning model of the purported sender to generate the user email.

Abstract: A multiple-input and multiple-output (MIMO) bolt-on device for a single-input and single-output (SISO) radio, a MIMO channel emulator for testing the MIMO bolt-on device, and a MIMO channel emulation method are provided. The MIMO bolt-on device includes: a plurality of antennas, a multi-channel receiver, a plurality of couplers, a micro-controller, and a switch device. The multi-channel receiver includes a plurality of channels for signal transmission. Each coupler is configured to couple the multi-channel receiver with one of the plurality of antennas. The micro-controller is coupled to the multi-channel receiver to compare signals from the plurality of channels, thereby identifying a channel with a highest signal-to-noise (SNR) among the plurality of channels. The switch device is coupled to the micro-controller and configured to select an antenna corresponding to the channel with the highest SNR among the plurality of antennas for a connection between a selected antenna and the SISO radio.

Abstract: Techniques described herein may be used to conserver battery power of an Internet of Things (IoT) tracker by increasing the overall amount of time that the IoT tracker is in a battery conservation mode (a sleep mode, a Power Save Mode (PSM), etc.). A IoT tracker may implement a battery conservation policy that may include instructions that cause the IoT tracker to monitor certain conditions, determine when the conditions satisfy a particular trigger, and implement a battery conservation mode in response to those conditions. Examples of such conditions may include (1) the IoT tracker being close to a user device designated to track the location of the IoT tracker, (2) identifying that a current time and day are associated with a pre-selected schedule for disabling tracking services, (3) the IoT tracker being located within a particular geographic area, and more.

Abstract: A charging apparatus includes a heat exchange pipeline, and a refrigerant liquid output pipe and a refrigerant liquid input pipe, which are connected to the heat exchange pipe. The charging apparatus can ensure a vehicle battery can be charged at an optimal temperature range, thereby reducing a charging time of the charging apparatus.

Abstract: A multiple-input and multiple-output (MIMO) bolt-on device for a single-input and single-output (SISO) radio, a MIMO channel emulator for testing the MIMO bolt-on device, and a MIMO channel emulation method are provided. The MIMO bolt-on device includes: a plurality of antennas, a multi-channel receiver, a plurality of couplers, a micro-controller, and a switch device. The multi-channel receiver includes a plurality of channels for signal transmission. Each coupler is configured to couple the multi-channel receiver with one of the plurality of antennas. The micro-controller is coupled to the multi-channel receiver to compare signals from the plurality of channels, thereby identifying a channel with a highest signal-to-noise (SNR) among the plurality of channels. The switch device is coupled to the micro-controller and configured to select an antenna corresponding to the channel with the highest SNR among the plurality of antennas for a connection between a selected antenna and the SISO radio.

Abstract: A network device receives one or more first key performance indicators (KPIs) associated with a cell site providing wireless service within a geographic area and determines at least one first capacity usage parameter associated with the cell site providing the wireless service. The network device determines placement of an additional antenna array within the geographic area to provide a certain coverage and capacity for the geographic area based on the one or more first KPIs and the determined at least one first capacity usage parameter.

Abstract: A method, a device, and a non-transitory storage medium are described in which a priority-based dynamic provisioning service is provided. A network device of an application service network may dynamically provision a function of the application service based on current resource utilization and one or multiple criteria. A spatial resolution or a progressive encoding of content delivered to users may dynamically change based on the dynamic provisioning of the function of the application service.

Abstract: The present invention provides an analyzer for predicting a prognosis of cancer radiotherapy, including a detection device and an arithmetic device. In a specimen, expression levels of a plurality of microRNAs (miRNAs) can be detected by the detection device. The miRNAs includes hsa-miR-130a-3p, hsa-miR-215-5p, hsa-miR-29a-3p, hsa-let-7b-5p, hsa-miR-19b-3p, hsa-miR-374a-5p and hsa-miR-148a-3p. The expression levels of miRNAs can be analyzed by the arithmetic device using logistic regression, and the analyzed values can be used to determine that the prognosis of cancer radiotherapy is poor or good.

Abstract: A method for estimating a risk for a subject suffering from an urothelial carcinoma is provided, including measuring an expression level of at least one miRNA in a sample of the subject, and the miRNA is selected from miR-1274, miR-19a, miR-30, and miR-708; and comparing the expression level of the same miRNA in the sample to that of a control for estimating whether the subject has the risk of suffering from the urothelial carcinoma or not. A kit for estimating a risk for a subject suffering from an urothelial carcinoma is also provided, including at least one reagent for detecting an expression level of at least one miRNA as above mentioned in a sample of the subject.

Abstract: A kit for detecting urothelial carcinoma is provided. The kit includes at least one primer or probe for detecting one or more miRNAs, and the one or more miRNAs are selected from the group consisting of miR-19b-1, miR-636, miR-150, miR-155, miR-183, miR-378, miR-210, miR-487, and combinations thereof. A method for detecting urothelial carcinoma is also provided. The method includes detecting the expression level(s) of one or more miRNAs in a sample of a subject, and the one or more miRNAs are selected from the group consisting of miR-19b-1, miR-636, miR-150, miR-155, miR-183, miR-378, miR-210, miR-487, and combinations thereof.

Abstract: An integrated electric booster braking system with a pedal force compensation function, comprising a booster motor, a first gear, a second gear, a lead screw, a brake master cylinder, a pedal push rod, a master cylinder push rod, a fluid storage tank, a hydraulic control unit and an electric control unit, wherein first gear and second gear are assembled in a housing, first gear is engaged with the second gear, the booster motor is connected with the first gear and drives the first gear to rotate, the first gear drives the second gear to rotate during rotation, the second gear is in threaded connection with the lead screw, the second gear drives the lead screw to move during rotation, the lead screw is of a hollow structure, and the rear end of the lead screw is abutted with the front end of a first piston in the brake master cylinder.

Abstract: Systems and methods described herein provide a multi-access edge computing (MEC) prediction service. A network device in a MEC network receives a predicted MEC route for an end device executing an application instance. The predicted MEC route identifies a projected time when the end device will connect to the network device for services and a service requirement for the application instance. The network device reserves resources to service the application instance at the projected time, based on the predicted MEC route. The network device provides a computing service for the application instance using the reserved resources when the end device initiates a data session with the network device.

Abstract: An example described herein includes a device to receive, from a user device, a request message to split processing, of an application, between the user device and the server device; determine a processing capability of the server device; and determine whether the server device is capable of executing a process of the application based on the processing capability of the server device. When the server device is determined to be capable of executing the process of the application, the device may: send an acceptance message to the user device, wherein the acceptance message identifies a first set of processes of the application and includes instructions to permit the user device to execute the first set of processes; and execute a second set of processes of the application, wherein the user device executes the first set of processes of the application substantially simultaneously as the server device executes the second set of processes of the application.

Abstract: An analog-to-digital converter is provided. The analog-to-digital converter is configured to convert an analog signal to a digital signal. The analog-to-digital converter includes a comparison circuit and a processing circuit. The comparison circuit is configured to compare the analog signal with each of a ramp signal and the ramp signal plus a predetermined offset to generate a control signal. The processing circuit, coupled to the comparison circuit, is configured to selectively store a count value of a counter circuit as the digital signal according to the control signal. When the control signal indicates that a signal level of the analog signal is greater than a signal level of the ramp signal and less than the signal level of the ramp signal plus the predetermined offset, the processing circuit is configured to store the count value as the digital signal.

Abstract: An analog-to-digital conversion circuit includes a first comparator, a second comparator and a counter circuit. The first comparator compares an analog signal with a ramp signal. The second comparator compares the analog signal with the ramp signal plus a predetermined offset. When a signal level of the ramp signal is less than a signal level of the analog signal, the counter circuit counts a number of clock cycles of a first clock signal to generate a first portion of a digital signal. When the signal level of the ramp signal plus the predetermined offset is greater than the signal level of the analog signal, the counter circuit counts a number of clock cycles of a second clock signal to generate a second portion of the digital signal. A frequency of the first clock signal is less than a frequency of the second clock signal.

Abstract: An output compensation circuit of an image sensor includes a first current mirror circuit, a first current generator circuit and a second current generator circuit. The first current mirror circuit, coupled to a select transistor of a pixel circuit of the image sensor, is configured to, in response to a first current, generate a second current flowing through the select transistor. The select transistor is selectively turned on according to a power supply voltage. When the select transistor is turned on, the pixel circuit outputs the second current through the select transistor. The first current generator circuit outputs a compensation current, serving as a first portion of the first current, to the first current mirror circuit in response to a variation in the power supply voltage. The second current generator circuit outputs a reference current, serving as a second portion of the first current, to the first current mirror circuit.

Abstract: A bullet comment processing method and apparatus, a server, and a storage medium are provided. When a bullet comment needs to be released, at least one candidate track matching a to-be-released bullet comment format is identified; then, a display duration of an existing bullet comment content in each candidate track is determined as a first duration corresponding to the each candidate track, and a display duration of a to-be-released bullet comment content when being placed in the each candidate track is determined as a second duration corresponding to the each candidate track; the second duration and the first duration of the each candidate track are compared, and a target track is identified to display the to-be-released bullet comment, where the second duration of the target track is greater than the first duration; and the to-be-released bullet comment content is displayed at the target track.