Abstract: Disclosed herein are grip sensing method and apparatus. The grip sensing method includes generating a sensing count by differentially amplifying a voltage potential of a grip channel based on a predetermined correction offset and performing digital conversion, comparing the sensing count with a predetermined base value to determine whether a touch condition is satisfied, performing baseline tracking for determining a baseline count based on the sensing count when the sensing count is less than the base value and the touch condition is not satisfied, stopping the baseline tracking and performing temperature compensation with respect to the baseline count using a temperature sensor mounted therein when the sensing count is equal to or greater than the base value and the touch condition is satisfied, and sensing an event based on the sensing count and the temperature-compensated baseline count.

Abstract: Disclosed herein are grip sensing method and apparatus. The grip sensing method includes generating a sensing count by differentially amplifying a voltage potential of a grip channel based on a predetermined correction offset and performing digital conversion, comparing the sensing count with a predetermined base value to determine whether a touch condition is satisfied, performing baseline tracking for determining a baseline count based on the sensing count when the sensing count is less than the base value and the touch condition is not satisfied, stopping the baseline tracking and performing temperature compensation with respect to the baseline count using a temperature sensor mounted therein when the sensing count is equal to or greater than the base value and the touch condition is satisfied, and sensing an event based on the sensing count and the temperature-compensated baseline count.

Abstract: Disclosed are a proximity sensor and a proximity detection method for the proximity sensor. The proximity sensor includes: a reception circuit configured to receive a first electrical signal which is generated based on proximity of the conductor; a first signal processing circuit configured to determine whether or not the conductor is in close proximity to the electronic device by using the first electrical signal, a first baseline value, and a threshold value; a temperature detection circuit configured to detect the temperature of the proximity sensor independently of the first electrical signal; and a second signal processing circuit configured to, when the conductor is in close proximity to the electronic device and also a temperature variation equal to or larger than a reference value is detected by the temperature detection circuit, generate a second baseline value by adding a temporary compensation value to the first baseline value.

Abstract: Disclosed are a proximity sensor and a proximity detection method for the proximity sensor. The proximity sensor includes: a reception circuit configured to receive a first electrical signal which is generated based on proximity of the conductor; a first signal processing circuit configured to determine whether or not the conductor is in close proximity to the electronic device by using the first electrical signal, a first baseline value, and a threshold value; a temperature detection circuit configured to detect the temperature of the proximity sensor independently of the first electrical signal; and a second signal processing circuit configured to, when the conductor is in close proximity to the electronic device and also a temperature variation equal to or larger than a reference value is detected by the temperature detection circuit, generate a second baseline value by adding a temporary compensation value to the first baseline value.

Abstract: Disclosed are an electronic device including a narrow bezel and a proximity sensing method for the electronic device. The electronic device includes: a first sensor configured to be arranged in a first area which is at least part of the non-display area of a front surface including a display, and to detect first capacitance between a first object in front of the front surface and the first sensor; a second sensor configured to be arranged in a first side surface adjacent to the first area, and to detect second capacitance between a second object in front of the first side surface and the second sensor; and a processor configured to generate sensing information by compensating the first capacitance based on the second capacitance, and to determine the proximity of the first object based on the sensing information.

Abstract: A capacitive touch panel is disclosed herein. The capacitive touch panel includes a plurality of bottom transparent electrodes formed in a first direction and a plurality of top transparent electrodes formed in a second direction perpendicular to the first direction. Each of the top transparent electrodes includes a linear electrode, a plurality of first pattern electrodes, and a plurality of second pattern electrodes. The linear electrode is linearly formed in the second direction. The plurality of first pattern electrodes is formed on the first side of the linear electrode in a predetermined first pattern, and is formed at predetermined intervals in an alternately protruding and recessed form in the second direction. The plurality of second pattern electrodes is formed on the second side of the linear electrode in a predetermined second pattern, and is formed at predetermined intervals in an alternately protruding and recessed form in the second direction.

Abstract: A capacitive touch panel is disclosed herein. The capacitive touch panel includes a plurality of bottom electrodes formed in a first direction and a plurality of top electrodes formed in a second direction perpendicular to the first direction. Each of the bottom electrodes includes a plurality of first protruding electrodes formed on the first side of the second direction with respect to an imaginary centerline, and formed in an alternately protruding and recessed form along the imaginary centerline, and a plurality of second protruding electrodes formed on a second side of the second direction with respect to the imaginary centerline, formed in an alternately protruding and recessed form along the imaginary centerline, and formed at locations interleaved with respect to those of the first protruding electrodes.

Abstract: A capacitive touch panel is disclosed herein. The capacitive touch panel includes a plurality of bottom electrodes formed in a first direction and a plurality of top electrodes formed in a second direction perpendicular to the first direction. Each of the bottom electrodes includes a plurality of first protruding electrodes formed on the first side of the second direction with respect to an imaginary centerline, and formed in an alternately protruding and recessed form along the imaginary centerline, and a plurality of second protruding electrodes formed on a second side of the second direction with respect to the imaginary centerline, formed in an alternately protruding and recessed form along the imaginary centerline, and formed at locations interleaved with respect to those of the first protruding electrodes.