A calibration method for calibrating a clock of a circuit for a smart card, which includes operations for: at a first instant, storing (S310) first time data from a terminal in the clock; at a second instant, reading (S320) second time data from the clock and corresponding to the first time data incremented by the clock as a function of a first duration between the first instant and the second instant; comparing (S330) the second time data with third time data corresponding to the first time data incremented, by the terminal or by a remote server, as a function of the first duration between the first instant and the second instant; as a function of the result of the comparison, calculating (S340) first calibration data; and storing (S350) the first calibration data in the clock. The reading of the second time data may be in a contactless manner.

A calibration method for calibrating a clock of a circuit for a smart card, which includes operations for: at a first instant, storing (S310) first time data from a terminal in the clock; at a second instant, reading (S320) second time data from the clock and corresponding to the first time data incremented by the clock as a function of a first duration between the first instant and the second instant; comparing (S330) the second time data with third time data corresponding to the first time data incremented, by the terminal or by a remote server, as a function of the first duration between the first instant and the second instant; as a function of the result of the comparison, calculating (S340) first calibration data; and storing (S350) the first calibration data in the clock. The reading of the second time data may be in a contactless manner.

Indicia-reading systems that interface with a user's nervous system include a device with electrodes capable of detecting electromagnetic signals produced in the brain or skeletal muscles of a user. The systems also include a computer with a processor and memory. The computer is configured to monitor the electromagnetic signals that are detected by the electrodes. The computer is also configured to perform operations in response to certain monitored electromagnetic signals. The computer may be an indicia-reading device configured to acquire indicia information in response to certain detected electromagnetic signals. The computer may also be a vehicle-mounted computer configured to sound an alarm in response to certain detected electromagnetic signals.

Indicia-reading systems that interface with a user's nervous system include a device with electrodes capable of detecting electromagnetic signals produced in the brain or skeletal muscles of a user. The systems also include a computer with a processor and memory. The computer is configured to monitor the electromagnetic signals that are detected by the electrodes. The computer is also configured to perform operations in response to certain monitored electromagnetic signals. The computer may be an indicia-reading device configured to acquire indicia information in response to certain detected electromagnetic signals. The computer may also be a vehicle-mounted computer configured to sound an alarm in response to certain detected electromagnetic signals.

A payment terminal such as a payment reader may receive and form electrical connections with an electronic transaction card such as an EMV chip card. The payment terminal may provide a clock signal at a rate that exceeds a specified rate for the EMV chip card. The payment terminal may transmit messages to the EMV chip card and monitor receive messages at a data connection. The payment terminal may determine that the clock rate is excessive based on a timeout of a receive message, an error rate of a receive message, or a receive message indicating that one of the transmit messages was not received by the EMV card. The payment terminal may reduce the clock rate to a rate that is below the specified rate for the EMV chip card.

A payment terminal such as a payment reader may receive and form electrical connections with an electronic transaction card such as an EMV chip card. The payment terminal may provide a clock signal at a rate that exceeds a specified rate for the EMV chip card. The payment terminal may transmit messages to the EMV chip card and monitor receive messages at a data connection. The payment terminal may determine that the clock rate is excessive based on a timeout of a receive message, an error rate of a receive message, or a receive message indicating that one of the transmit messages was not received by the EMV card. The payment terminal may reduce the clock rate to a rate that is below the specified rate for the EMV chip card.

The present disclosure provides a display device, a control method thereof, and a computer storage medium, relating to the technical field of displays. The display device includes a control component, and the control component is configured to control a display component to operate; and control, in response to receiving a first control instruction, at least one of a near-field communication component and the display component such that a signal-sending period of the near-field communication component falls within an image-holding period of the display component, wherein the near-field communication component is configured to send a signal during the signal-sending period. According to the method, the signal-sending period is caused to be within the image-holding period by controlling at least one component of the near-field communication component and the display component during a display of the display component, such that the near-field communication component is prevented from affecting the image refresh of the display component when sending the signal, and thus the poor display effect of the display device in the related art is solved, and a display effect of the display device is further improved.

The present disclosure provides a display device, a control method thereof, and a computer storage medium, relating to the technical field of displays. The display device includes a control component, and the control component is configured to control a display component to operate; and control, in response to receiving a first control instruction, at least one of a near-field communication component and the display component such that a signal-sending period of the near-field communication component falls within an image-holding period of the display component, wherein the near-field communication component is configured to send a signal during the signal-sending period. According to the method, the signal-sending period is caused to be within the image-holding period by controlling at least one component of the near-field communication component and the display component during a display of the display component, such that the near-field communication component is prevented from affecting the image refresh of the display component when sending the signal, and thus the poor display effect of the display device in the related art is solved, and a display effect of the display device is further improved.

A multi-protocol RFID interrogating system employs a synchronization technique (step-lock) for a backscatter RFID system that allows simultaneous operation of closely spaced interrogators. The multi-protocol RFID interrogating system can communicate with backscatter transponders having different output protocols and with active transponders including: Title 21 compliant RFID backscatter transponders; IT2000 RFID backscatter transponders that provide an extended mode capability beyond Title 21; EGOTM RFID backscatter transponders, SEGOTM RFID backscatter transponders; ATA, ISO, ANSI AAR compliant RFID backscatter transponders; and IAG compliant active technology transponders. The system implements a step-lock operation, whereby adjacent interrogators are synchronized to ensure that all downlinks operate within the same time frame and all uplinks operate within the same time frame, to eliminate downlink on uplink interference.

A multi-protocol RFID interrogating system employs a synchronization technique (step-lock) for a backscatter RFID system that allows simultaneous operation of closely spaced interrogators. The multi-protocol RFID interrogating system can communicate with backscatter transponders having different output protocols and with active transponders including: Title 21 compliant RFID backscatter transponders; IT2000 RFID backscatter transponders that provide an extended mode capability beyond Title 21; EGOTM RFID backscatter transponders, SEGOTM RFID backscatter transponders; ATA, ISO, ANSI AAR compliant RFID backscatter transponders; and IAG compliant active technology transponders. The system implements a step-lock operation, whereby adjacent interrogators are synchronized to ensure that all downlinks operate within the same time frame and all uplinks operate within the same time frame, to eliminate downlink on uplink interference.