Abstract: An apparatus for 5G security management of a malicious device based on an open-radio access network (O-RAN) architecture includes a service management orchestration (SMO) unit, an O-RAN element unit and an artificial intelligence (AI) processing unit. The SMO unit includes a non-real time radio access network intelligent controller (non-RT RIC). The non-RT RIC collects a non-real time traffic data of a user. The O-RAN element unit includes a near-real time radio access network intelligent controller (near-RT RIC). The near-RT RIC collects a near-real time traffic data of the user. The AI processing unit is configuring to classify the user into one of a plurality of categories, predict at least one traffic index of the user, and determine whether the user is the malicious device.

Abstract: A two-way signal positioning method and a two-way signal positioning system thereof are disclosed. The method includes the following steps: controlling a locating device to be measured to transmit a plurality of positioning signals of a plurality of transmission powers; causing a plurality of known locating devices to receive the plurality of positioning signals and return a plurality of response signals to the locating device to be measured; recording the strengths of the plurality of positioning signals, the strengths of the plurality of response signals, the plurality of corresponding receiving times and the coordinates of the plurality of known locating devices to a database; identifying the known locating devices corresponding to the stronger signals; and obtaining a signal strength-distance function and a signal strength-distance standard deviation function from the database so as to identify the device location of the locating device to be measured.

Abstract: A dynamic power positioning method and a dynamic power positioning system thereof are disclosed. The method comprises the steps of: controlling a device to be measured to transmit a plurality of positioning signals with a plurality of transmission powers; making a plurality of known location devices to receive the plurality of positioning signals, and recording the intensities and the corresponding reception times of the plurality of positioning signals, and the coordinates of the plurality of known location devices to the database; finding out the known location device corresponding to a positioning signal having a higher signal intensity among the received plurality of positioning signals; obtaining a signal intensity-distance function and a signal intensity-distance standard deviation function from the database; and finding out the device location of the device to be measured according to the signal intensity-distance function and signal intensity-distance standard deviation function.

Abstract: A two-way signal positioning method and a two-way signal positioning system thereof are disclosed. The method includes the following steps: controlling a locating device to be measured to transmit a plurality of positioning signals of a plurality of transmission powers; causing a plurality of known locating devices to receive the plurality of positioning signals and return a plurality of response signals to the locating device to be measured; recording the strengths of the plurality of positioning signals, the strengths of the plurality of response signals, the plurality of corresponding receiving times and the coordinates of the plurality of known locating devices to a database; identifying the known locating devices corresponding to the stronger signals; and obtaining a signal strength-distance function and a signal strength-distance standard deviation function from the database so as to identify the device location of the locating device to be measured.

Abstract: A power positioning method and a power positioning device thereof are disclosed. The method comprises the steps of: controlling a device to be measured to transmit a plurality of positioning signals by a plurality of transmission powers; causing a plurality of known location devices to receive the plurality of positioning signals and recording the plurality of positioning signals and a plurality of corresponding receiving time to a database; finding out the known location device with a large signal intensity among the received plurality of positioning signals; taking out a signal intensity-distance function and a signal intensity-distance standard deviation function from the database; and finding out a device location of the device to be measured according to the signal intensity-distance function and the signal intensity-distance standard deviation function.

Abstract: A power positioning method and a power positioning device thereof are disclosed. The method comprises the steps of: controlling a device to be measured to transmit a plurality of positioning signals by a plurality of transmission powers; causing a plurality of known location devices to receive the plurality of positioning signals and recording the plurality of positioning signals and a plurality of corresponding receiving time to a database; finding out the known location device with a large signal intensity among the received plurality of positioning signals; taking out a signal intensity-distance function and a signal intensity-distance standard deviation function from the database; and finding out a device location of the device to be measured according to the signal intensity-distance function and the signal intensity-distance standard deviation function.

Abstract: A dynamic power positioning method and a dynamic power positioning system thereof are disclosed. The method comprises the steps of: controlling a device to be measured to transmit a plurality of positioning signals with a plurality of transmission powers; making a plurality of known location devices to receive the plurality of positioning signals, and recording the intensities and the corresponding reception times of the plurality of positioning signals, and the coordinates of the plurality of known location devices to the database; finding out the known location device corresponding to a positioning signal having a higher signal intensity among the received plurality of positioning signals; obtaining a signal intensity-distance function and a signal intensity-distance standard deviation function from the database; and finding out the device location of the device to be measured according to the signal intensity-distance function and signal intensity-distance standard deviation function.

Abstract: A scheduling method of uplink resource unit includes selecting an uplink parameter set, by calculating the uplink parameter set capable of achieving a minimized energy consumption according to a traffic and a QoS of a user equipment (UE). The uplink parameter set allows a plurality of transmission variations. A score function is used to calculate a score of a transmission condition variation of the UE and a transmission order of the UE is determined according to the score. A disposing position of the resource units in uplink subcarriers is determined. The time occupied by the disposing position is checked to see whether or a delay constraint allowed by the UE is satisfied. If the result of checking the disposing position does not satisfy the delay constraint, the number of consecutive subcarriers is changed and the step of determining the disposing position of the resource units in the uplink subcarriers is repeatedly performed.

Abstract: A scheduling method of uplink resource unit includes selecting an uplink parameter set, by calculating the uplink parameter set capable of achieving a minimized energy consumption according to a traffic and a QoS of a user equipment (UE). The uplink parameter set allows a plurality of transmission variations. A score function is used to calculate a score of a transmission condition variation of the UE and a transmission order of the UE is determined according to the score. A disposing position of the resource units in uplink subcarriers is determined. The time occupied by the disposing position is checked to see whether or a delay constraint allowed by the UE is satisfied. If the result of checking the disposing position does not satisfy the delay constraint, the number of consecutive subcarriers is changed and the step of determining the disposing position of the resource units in the uplink subcarriers is repeatedly performed.

Abstract: A cross-layer method for sleep scheduling is executed by a base station serving to at least one mobile device, and the method comprises the steps of: searching for a plurality of environment parameters of the base station and the at least one mobile device; dynamically allocating at least one subframe to a first scheduling block of the at least one mobile device for achieving an initial schedule according to the plurality of environment parameters; and dynamically adjusting the first scheduling block of the at least one mobile device in the at least one subframe and at least one modulation and coding scheme corresponding to the first scheduling block for achieving a real-time schedule according to the plurality of environment parameters and the initial schedule.

Abstract: An analyzing system and a method for evaluating calorie consumption by detecting the intensity of wireless signal are provided. The analyzing system includes a wireless receiving device, a processor and a calorie consumption computing device. The wireless receiving device receives a first wireless signal emitted from a first wireless transmitting device. The wireless receiving device detects a first intensity of the first wireless signal at a first time, and detects a second intensity of the first wireless signal at a second time. The processor obtains a motion information corresponding from the first time to the second time according to the first intensity of the first wireless signal and the second intensity of the first wireless signal. The calorie consumption computing device generates a calorie consumption according to the motion information.

Abstract: A method for vehicle positioning is provided, which includes the steps of identifying at least one vehicle in an image, obtaining identification information of each vehicle from the image, and transforming coordinates of each vehicle in the image into positioning information of the corresponding vehicle according to mapping information. The positioning information is a position of the corresponding vehicle in real world. Precise lane-level vehicle positioning can be achieved based on comparison with the identification information or the positioning information.

Abstract: The present invention is to provide a safety monitoring system, which includes a plurality of terminal devices (e.g., smartphones) each configured to wirelessly and periodically send out a report message and a home server storing positioning data created according to the strengths of signals transmitted by each terminal device from different locations within an indoor environment (e.g., an apartment) respectively. According to the positioning data, the home server divides the indoor environment into a plurality of monitoring areas (e.g., living room, bathrooms, kitchen . . . ). When the home server receives the report message and determines the monitoring area where each terminal device is located according to the positioning data, the home server uploads entry of identification data and the monitoring area corresponding to each terminal device to a cloud server through the Internet. Thus, the current status of the carrier of each terminal device can be checked through the cloud server.

Abstract: A wireless network is provided. The wireless network includes a predetermined wireless router and a plurality of wireless routers. The predetermined wireless router has gateway functionality for accessing an external network. Each wireless router of the wireless routers has a single transceiver, and the wireless routers include at least a wireless router which communicates with other wireless router(s) in the wireless network for forwarding network packets by using a single fixed channel and at least a wireless router which communicates with other wireless router(s) in the wireless network for forwarding network packets by using a plurality of channels.

Abstract: A positioning method and a positioning system based on light intensity are provided. The positioning system comprises a lighting system, a sense feedback device and a positioning module. The lighting system comprises at least three point light sources and sequentially adjusts luminance of these point light sources to light up a target. The sense feedback device is disposed on the target and used to collect light intensity information of the light projected on the target by the lighting system. The positioning module calculates a distance between the target and each of the point light sources based on the light intensity information and calculates a positioning location of the target based on the locations of the point light sources and the distances between the target and the point light sources.

Abstract: The present invention is to provide a safety monitoring system, which includes a plurality of terminal devices (e.g., smartphones) each configured to wirelessly and periodically send out a report message and a home server storing positioning data created according to the strengths of signals transmitted by each terminal device from different locations within an indoor environment (e.g., an apartment) respectively. According to the positioning data, the home server divides the indoor environment into a plurality of monitoring areas (e.g., living room, bathrooms, kitchen . . . ). When the home server receives the report message and determines the monitoring area where each terminal device is located according to the positioning data, the home server uploads entry of identification data and the monitoring area corresponding to each terminal device to a cloud server through the Internet. Thus, the current status of the carrier of each terminal device can be checked through the cloud server.

Abstract: A method for vehicle positioning is provided, which includes the steps of identifying at least one vehicle in an image, obtaining identification information of each vehicle from the image, and transforming coordinates of each vehicle in the image into positioning information of the corresponding vehicle according to mapping information. The positioning information is a position of the corresponding vehicle in real world. Precise lane-level vehicle positioning can be achieved based on comparison with the identification information or the positioning information.

Abstract: The present invention provides a positioning method for long-thin fleet, which moves along a direction and has a motion track and a leading member. The leading member is in forefront of the motion track. The positioning method comprises the following steps: a positioning step and a transmitting step. The positioning step gets a positioning data through a GPS in a preset time. The transmitting step transmits a periodic signal to the members of the fleet through a wireless network system. The leading member proceeds the positioning and transmitting steps. The motion track is connected according to the positioning data.

Abstract: The present invention is to provide a sensing method applicable to a sensing system including at least one detecting device and a mobile communication device, wherein the detecting device is electrically connected between an electrical appliance and a power supply unit for detecting usage information (e.g., voltage value, current value, power value, etc.) of the electricity transmitted from the power supply unit to the electrical appliance, and the mobile communication device is wirelessly connected to the detecting device and is able to transmit setting data inputted by a user to the detecting device so that, after receiving the setting data, the detecting device is able to periodically transmit the electricity usage information to the mobile communication device, allowing the mobile communication device to convert the electricity usage information into a detecting chart and graphically display the detecting chart on a screen of the mobile communication device.

Abstract: In a machine-implemented method for use with a handheld device, a user is able to virtually try on a selected garment using augmented reality. The machine-implemented method includes: (A) establishing a garment database containing information corresponding to at least one garment, the information corresponding to each garment including a backside image of the garment; (B) establishing a marker database containing feature information of a backside marker; and (C) upon determining from a captured image of the user who is tagged with at least one physical maker that the physical marker corresponds to the backside marker, retrieving from the garment database the backside image of a selected garment, and superimposing the retrieved backside image onto the captured image of the user to form a composite image for display on a screen of the handheld device.