An electronic device includes a first source group and a second source group, each of which includes a plurality of source channels, and a gamma block that receives first to 2i-th initial voltages (i being an integer of 1 or more), outputs first to 2i-th intermediate voltages by amplifying the first to i-th initial voltages, and outputs first to i-th gamma voltages to the first source group by buffering the first to 2i-th intermediate voltages, and a first buffer block that receives the first to 2i-th intermediate voltages from the gamma block and buffers the first to 2i-th intermediate voltages so as to be output to the second source group, and the gamma block may include a first resistor string including a plurality of resistors connected between nodes from which the first to i-th gamma voltages are output.

A voltage converter includes an input voltage line; an inductor coupled to the input voltage line; transistors coupled to the inductor; an output voltage line coupled to at least one of the transistors; a current sensor coupled to at least one of the input voltage line, the inductor, or the output voltage line; and a comparator coupled between the current sensor and the transistors. A DC-DC converter may include a voltage converter having an inductor and a plurality of transistors and configured to convert an input voltage into a power voltage and output the power voltage to an output terminal, an input current sensor configured to sense the input current of the converter, and a controller configured to change the slew rate of an inductor voltage in response to the input current of the converter and a preset reference current.

A lighting system includes an LED array having a plurality of LED pixels and a power controller. The power controller adjusts a supply voltage for powering the LED pixels based on one or more conditions of the LED array. The power controller may determine the supply voltage based on process data of the LED array. The power controller may adjust the supply voltage based on an operating temperature of the LED pixels and the amplitude of a current driving the LED pixels.

A low drop-out (LDO) regulator includes a power transistor, an error amplifier and a droop adjusting circuit. The power transistor regulates a driving voltage based on a gate voltage of a gate node to provide an output voltage at an output node. The error amplifier outputs the gate voltage by amplifying a voltage difference between a reference voltage and a feedback voltage proportional to the output voltage. The droop adjusting circuit is connected between the gate node and the output node, is coupled to the output voltage, and adjusts the gate voltage to compensate for a change of the output voltage based on a change of a load current which is provided to a load from the output node.

Provided is a display device which comprises a display panel including a plurality of pixels displaying an image based on a driving voltage, a reference voltage generator converting a sensing driving voltage generated by measuring the driving voltage into a sensing driving current, converting a preset reference driving voltage into a reference driving current, comparing the sensing driving current and the reference driving current, and generating a first reference voltage and a second reference voltage based on a difference between the sensing driving current and the reference driving current, a gamma voltage generator generating a plurality of gamma voltages by dividing the first reference voltage and the second reference voltage, and a data driver converting image data into a data voltage based on the gamma voltages and providing the data voltage to each of the pixels.

Provided is a display device comprising a display panel, an image shift controller, and a controller. The display panel is configured to display a display image, and includes a display area in which pixels are disposed and a sub-display area surrounding the display area and in which dummy pixels are disposed. The image shift controller is configured to generate a display image shift signal including information on a path through which the display image is shifted. The controller is configured to receive the display image shift signal to generate input image data to which the display image shift signal is applied. A size of a driving transistor included in each of the pixels disposed in the display area is different from a size of a driving transistor included in each of the dummy pixels disposed in the sub-display area.

A method for operating an electronic shelf label system, wherein the system comprises shelf labels fastened to shelf edge strips, wherein the shelf labels are designed such that they can be supplied with energy in a contactless manner, and the shelf edge strip comprises a supply device for contactlessly supplying energy to the shelf labels fastened on it, and the shelf edge strip comprises at least one conductor loop, wherein the conductor loop is a constituent of the supply device of the shelf edge strip and the conductor loop is used for emitting a signal, which can be generated by the supply device, for the purpose of the said supply of energy of shelf labels positioned on the shelf edge strip in a manner corresponding to the conductor loop, wherein according to the method, the said signal is generated with the aid of the supply device and emitted via the conductor loop and the respective shelf label positioned corresponding to the conductor loop stores electrical energy, which is transmitted with the aid of the signal from the supply device to the shelf label, in a rechargeable long-term energy storage device and uses the same for its operation outside of a time period where the signal is present.

A display device includes a first transistor including a first channel region, a first gate electrode overlapping the first channel region, and a first electrode connected to a node receiving a driving voltage, a second transistor electrically connected to the first electrode of the first transistor, the second transistor including a second channel region and a second gate electrode overlapping the first channel region and receiving a scan signal, a light emitting element electrically connected to a second electrode of the first transistor, a first conductive line overlapping the first gate electrode with the first channel region in between and receiving a variable voltage different from the driving voltage, and a second conductive line overlapping the second gate electrode with the second channel region in between and receiving the scan signal.

The present disclosure provides a display device. The display device includes at least one display panel including at least one light-emitting diode (LED) light board, a drive control module connected to the LED light board, and a detecting module respectively connected to the LED light board and the drive control module. The LED light board includes at least one LED. The drive control module is configured to drive the LED of the LED light board to display.

An organic light emitting diode (OLED) display device includes a first power supply circuit configured to generate a pixel driving voltage, a display panel configured to receive the pixel driving voltage from the first power supply circuit, and including a plurality of pixels each configured to emit light based thereon, and a scan driver configured to receive the pixel driving voltage from the display panel, and to provide scan signals based on the pixel driving voltage to the plurality of pixels.