Abstract: Disclosed is a method for controlling an alternator of a vehicle that can change a Pulse Width Modulation (PWM) duty cycle change rate to reach a target PWM duty cycle after completion of an initial engine stabilization. According to the method, PWM duty cycle is increased using an initial rate received from an ECU to prevent an engine overload from occurring when a current PWM duty cycle is less than a predetermined reference duty cycle. When the current PWM duty cycle becomes higher than the predetermined reference duty cycle, PWM duty cycle change rate can be adjusted to flexibly suppress engine RPM fluctuation and vibration in real time and to improve a response speed of an alternator output voltage.

Abstract: Disclosed is a method for controlling an alternator of a vehicle that can change a Pulse Width Modulation (PWM) duty cycle change rate to reach a target PWM duty cycle after completion of an initial engine stabilization. According to the method, PWM duty cycle is increased using an initial rate received from an ECU to prevent an engine overload from occurring when a current PWM duty cycle is less than a predetermined reference duty cycle. When the current PWM duty cycle becomes higher than the predetermined reference duty cycle, PWM duty cycle change rate can be adjusted to flexibly suppress engine RPM fluctuation and vibration in real time and to improve a response speed of an alternator output voltage.

Abstract: The present invention relates to a monitoring method and a monitoring apparatus using a camera. According to an embodiment of the present invention, a monitoring method using a camera includes receiving a photographed input image from the camera; detecting an object existing in the input image and positional information of the object; generating a corrected image by correcting a distorted area of the input image; and generating a synthesized image by synthesizing alarm display information which is generated on the basis of the object and the positional information, with the corrected image, and outputting the synthesized image through a display.

Abstract: The present invention relates to a monitoring method and a monitoring apparatus using a camera. According to an embodiment of the present invention, a monitoring method using a camera includes receiving a photographed input image from the camera; detecting an object existing in the input image and positional information of the object; generating a corrected image by correcting a distorted area of the input image; and generating a synthesized image by synthesizing alarm display information which is generated on the basis of the object and the positional information, with the corrected image, and outputting the synthesized image through a display.

Abstract: A dead pixel compensating apparatus includes, inter alia, a pattern generation unit generating a programmable test pattern including data with respect to at least one dead pixel; a register array storing the test pattern; a dead pixel compensation unit receiving the test pattern stored in the register array and performing a dead pixel compensation algorithm to output compensation data; and a determination unit comparing the test pattern and the compensation data to determine whether or not the dead pixel compensation algorithm has an error, wherein a dead pixel compensation algorithm for compensating for a dead pixel of an image sensor in image data supplied from the image sensor is tested.

Abstract: A dead pixel compensating apparatus includes, inter alia, a pattern generation unit generating a programmable test pattern including data with respect to at least one dead pixel; a register array storing the test pattern; a dead pixel compensation unit receiving the test pattern stored in the register array and performing a dead pixel compensation algorithm to output compensation data; and a determination unit comparing the test pattern and the compensation data to determine whether or not the dead pixel compensation algorithm has an error, wherein a dead pixel compensation algorithm for compensating for a dead pixel of an image sensor in image data supplied from the image sensor is tested.

Abstract: A plasma display device (PDP) and method of driving it (during an address period) are provided. Such a PDP has an address electrode for receiving an address pulse and a capacitor. Such an address pulse has states including a first voltage and a smaller second voltage smaller. Such a capacitor stores a third voltage that is between the first and third voltages. Such a method includes: coupling the capacitor to the address electrode via the inductor; firstly energizing, via the inductor, the address electrode with the third voltage stored in the capacitor; secondly energizing the address electrode with the first voltage; thirdly energizing, via the inductor, the capacitor with voltage on the address electrode; and fourthly energizing the address electrode with the second voltage. Real power transfer during the first and third energizations is facilitated via reactive power transfer arising from LC resonance.

Abstract: In a Plasma Display Device (PDP) and driving method thereof to reduce Electro Magnetic Interference (EMI), address electrodes are divided according to colors controlled by the address electrodes in the address period and voltages are supplied to the electrodes at different times to reduce EMI, and red, green, and blue discharge cells are controlled to concurrently emit light to display natural colors clearly.

Abstract: A method and apparatus and program storage device to drive a display panel having a plurality of address electrode groups includes driving the display panel to transmit digital data at a time difference for each group of address electrodes and varying the respective time difference for each group of address electrodes according to a load factor of each group of address electrodes.

Abstract: A PDP address data processor, a method thereof, and a recording medium for storing a program used to perform the method. The address data processor generates subfield data corresponding to RGB input video data, divides them into two sets of subfield data, and stores them in a frame memory using rising and falling edges of a reference clock signal of a frame memory. The address data processor reads and arranges the stored subfield data using the rising and falling edges to generate address data for representing gray on the PDP. The address data processor uses an RGB mixing algorithm for selecting two different video data from among the RGB input video data to select video data, and generates the subfield data corresponding to the selected video data.

Abstract: A plasma display device determining whether to perform power recovery in address and sustain periods of each subfield according to the temperature of a plasma display panel. When the temperature is outside of a predetermined temperature range, the address voltage is applied by hard switching to the third electrode in order to select the discharge cell to be displayed among the discharge cells in the address period. The sustain discharge pulse voltage is applied by the hard switching to the first and second electrodes in a first group of the sustain period, the sustain period being divided into at least two groups. The sustain discharge pulse voltage is applied by inductor-capacitor resonance of a power recovery circuit to the first and second electrodes in a second group of the sustain period.

Abstract: A PDP address data processor, a method thereof, and a recording medium for storing a program used to perform the method. The address data processor generates subfield data corresponding to RGB input video data, divides them into two sets of subfield data, and stores them in a frame memory using rising and falling edges of a reference clock signal of a frame memory. The address data processor reads and arranges the stored subfield data using the rising and falling edges to generate address data for representing gray on the PDP. The address data processor uses an RGB mixing algorithm for selecting two different video data from among the RGB input video data to select video data, and generates the subfield data corresponding to the selected video data.

Abstract: A plasma display panel is provided having a plurality of scan electrodes and sustain electrodes formed parallel to each other in pairs on a first substrate, and a plurality of address electrodes formed on a second substrate that cross the plurality of first and second electrode pairs. A reset waveform is applied to a scan electrode during a reset period, and a scan pulse that falls from a first voltage level to a second voltage level is applied to the can electrode during an address period. A pre-scan pulse of a third voltage level, which is higher than the first voltage level, is applied to a scan electrode between the reset and address periods, and either a magnitude of the third voltage level or a width of the pre-scan pulse is adjusted according to patterns of subfield data.

Abstract: A plasma display device. A plasma display panel includes a plurality of address electrodes, a plurality of scan electrodes, and a plurality of sustain electrodes. A temperature detector detects a temperature of the plasma display panel. A controller outputs a scan electrode driving signal to control a reset waveform to be applied during reset periods of a first number of subfields when the detected temperature between a first temperature and a second temperature, and to control a reset waveform to be applied during reset periods of a second number of subfields when the detected temperature is lower than the first temperature and higher than the second temperature. The second number of subfields is greater than the first number of subfields. A scan electrode driver applies the appropriate reset waveform during a reset period of a subfield according to the scan electrode driving signal output from the controller.

Abstract: A method for driving a plasma display panel including a plurality of pixels, a plurality of first electrode lines, a plurality second electrode lines, and a plurality of third electrode lines crossing the first electrode lines and the second electrode lines, and being driven by dividing a frame into a plurality of subfields, each subfield including a reset period, an address period and a sustain discharge period, the method including: applying a first pre-address signal to a first group of third electrode lines among the plurality of third electrode lines in a pre-address period, the pre-address period being between the reset period and the address period in at least one of the subfields; and applying a second pre-address signal to at least a second group of third electrode lines among the plurality of third electrode lines in the pre-address period.

Abstract: A plasma display and a driving method thereof are disclosed. The plasma display includes a plurality of address electrodes; an address electrode driver that includes at least one power recovering capacitor and a plurality of address driving circuits having a plurality of first switches controlling current paths between the power recovering capacitor and the address electrodes. The driver circuit turns on the first switch during a first period of when the voltage of the address electrode is changed from a first voltage to a second voltage and during a second period of when the voltage of the address electrode is changed from the second voltage to the first voltage. The display also has a controller that divides one field into a plurality of subfields each having a weight value and controls the duration of at least one of the first period and the second period according to the weight value of each subfield.

Abstract: A plasma display device (PDP) and method of driving it (during an address period) are provided. Such a PDP has an address electrode for receiving an address pulse and a capacitor. Such an address pulse has states including a first voltage and a smaller second voltage smaller. Such a capacitor stores a third voltage that is between the first and third voltages. Such a method includes: coupling the capacitor to the address electrode via the inductor; firstly energizing, via the inductor, the address electrode with the third voltage stored in the capacitor; secondly energizing the address electrode with the first voltage; thirdly energizing, via the inductor, the capacitor with voltage on the address electrode; and fourthly energizing the address electrode with the second voltage. Real power transfer during the first and third energizations is facilitated via reactive power transfer arising from LC resonance.

Abstract: A plasma display device. A plasma display panel includes a plurality of address electrodes, a plurality of scan electrodes, and a plurality of sustain electrodes. A temperature detector detects a temperature of the plasma display panel. A controller outputs a scan electrode driving signal to control a reset waveform to be applied during reset periods of a first number of subfields when the detected temperature between a first temperature and a second temperature, and to control a reset waveform to be applied during reset periods of a second number of subfields when the detected temperature is lower than the first temperature and higher than the second temperature. The second number of subfields is greater than the first number of subfields. A scan electrode driver applies the appropriate reset waveform during a reset period of a subfield according to the scan electrode driving signal output from the controller.

Abstract: A plasma display device. A plasma display panel includes a plurality of address electrodes, a plurality of scan electrodes, and a plurality of sustain electrodes. A temperature detector detects a temperature of the plasma display panel. A controller outputs a scan electrode driving signal to control a reset waveform to be applied during reset periods of a first number of subfields when the detected temperature between a first temperature and a second temperature, and to control a reset waveform to be applied during reset periods of a second number of subfields when the detected temperature is lower than the first temperature and higher than the second temperature. The second number of subfields is greater than the first number of subfields. A scan electrode driver applies the appropriate reset waveform during a reset period of a subfield according to the scan electrode driving signal output from the controller.

Abstract: A plasma display device. A plasma display panel includes a plurality of address electrodes, a plurality of scan electrodes, and a plurality of sustain electrodes. A temperature detector detects a temperature of the plasma display panel. A controller outputs a scan electrode driving signal to control a reset waveform to be applied during reset periods of a first number of subfields when the detected temperature between a first temperature and a second temperature, and to control a reset waveform to be applied during reset periods of a second number of subfields when the detected temperature is lower than the first temperature and higher than the second temperature. The second number of subfields is greater than the first number of subfields. A scan electrode driver applies the appropriate reset waveform during a reset period of a subfield according to the scan electrode driving signal output from the controller.