Abstract:
An information processing apparatus includes a first processor, a second processor and a positioning processor. The second processor consumes a reduced amount of power compared to the first processor during an operation. The positioning processor receives radio waves from positioning satellites and converts the radio waves into positioning data. The second processor controls the positioning processor. The second processor stores the positioning data received from the positioning processor. The second processor transfers the stored positioning data to the first processor at a timing determined in accordance with an operating condition of the first processor.
Abstract:
An information processing apparatus includes: a communication unit that performs wireless communication with an external apparatus; a first control unit that switches between a normal state and a low electric power consumption state that suppresses electric power consumption to less than the normal state; and a second control unit that operates at lower electric power consumption than the first control unit, in which the information processing apparatus controls a connection state of the communication unit with the first control unit and the second control unit, based on a state of the information processing apparatus.
Abstract:
A display device includes a display, a touch panel and a controller. The display includes a plurality of display panels laminated on one another. The touch panel is provided on a screen of the display and accepts touch operation. The controller determines with respect to which display panel among the plurality of display panels the touch operation is carried out, and carries out a process corresponding to operation content of the touch operation on the determined display panel.
Abstract:
An information processing apparatus includes a processor that periodically acquires output values from a sensor in a state where the sensor is worn adjacent to a body of a user via a wearable device, derives amplitude parameters representing amplitudes of a plurality of output values among the output values acquired from the sensor, the plurality of output values having been acquired at a plurality of different timings within a preset determination period, counts the number of amplitude parameters that are larger than a criterial value, among the derived amplitude parameters each representing a respective one of a plurality of amplitudes generated at different timings, the number being defined as an amplitude count for determination, and determines whether the wearable device is properly worn on the body of the user based on the amplitude count for determination.
Abstract:
An input terminal connected to both a terminal of the first device outputting a signal including a period of a low voltage greater than or equal to a predetermined period and a terminal of the second device outputting a periodic signal alternately repeating a high voltage and a low voltage less than the predetermined period via one signal line is included. When a signal input to the input terminal includes a period of a low voltage greater than or equal to the predetermined period, it is determined that a signal output from the first device is input.
Abstract:
An increase in power consumption involved in calibration for calibrating an offset of a geomagnetism sensor is suppressed. An electronic device performs calibration of an output error of the geomagnetism sensor so that the geomagnetism sensor can output more accurate geomagnetism data based on angular speed data output by a gyro sensor. The electronic device controls turning ON/OFF of the gyro sensor. The electronic device determines whether or not calibration of the geomagnetism sensor is necessary. When it is determined that calibration of the geomagnetism sensor is unnecessary, the electronic device performs a control operation to turn OFF the gyro sensor.
Abstract:
A wearable information device is configured to store device identifying information used for identifying the information device registered in advance, to confirm whether or not a taken image, in which an object in a direction of line of vision of a user is taken, shows the information, by image analysis based on the stored device identifying information, and to notify the information device of a result of the confirmation. The information device is configured to execute a predetermined function on the basis of the result of the confirmation of the information device notified from the wearable information device.
Abstract:
An electronic device includes a biometric detection value acquirer to acquire a biometric detection value for calculation of biometric information of a wearer of the electronic device and a processor, in which the processor estimates a change trend of information related to an action detail of the wearer and, based on the estimated change trend of information related to an action detail, selects an algorithm to calculate the biometric information from the biometric detection value.
Abstract:
An electronic device includes first and second processors, and first and second display units. While the first and second processors cooperate with each other and perform a display operation including a time display, the first processor can be set to a normal mode, a low power mode in which a power consumption is lower than a power consumption in the normal mode, or a pause mode in which a power consumption is lower than the power consumption in the low power mode, and the first processor is stopped. In the normal or low power modes, the first processor controls such that the first display unit displays a time, and the second processor controls such that the second display unit does not display a time. In the pause mode, the first display unit is turned off, and the second processor controls such that the second display unit displays a time.
Abstract:
Provided is an electronic apparatus in which an illuminance sensor is arranged on the back side of a display unit, and which can perform the appropriate luminance adjustment. The electronic apparatus includes a display unit, an illuminance sensor, a luminance control unit, and an operation judgement unit. The illuminance sensor is disposed on back side of the display surface of the display unit. The luminance control unit controls the luminance of the display unit based on the information related to light detected by the illuminance sensor. The operation judgement unit judges reliability of the information related to light detected by the illuminance sensor. The luminance control unit controls the luminance of the display unit when reliability is judged to be high. The luminance control unit suppresses control of the luminance of the display unit when reliability is judged to be low.