Apparatus and method for controlling capture of image of cut surface

What is claimed is: 1. An apparatus for controlling capture of an image of a cut surface of material that is cut by a cutting device, comprising: a signal generation unit, located at an area within which the cutting device moves, for outputting a signal; a sensor unit for sensing the output signal using multiple sensors and for generating a sensing signal; and an image capture control unit for controlling an image-capturing operation of an imaging device, which captures the image of the cut surface, using the sensing signal, wherein each of the multiple sensors are configured to change from a standby state to a sensing state, wherein the image capture control unit comprises: a sensing signal reception module for receiving the sensing signal from the sensor unit; an operational state control module for creating an image capture instruction using the sensing signal of the sensor; and an image capture signal transmission module for transmitting the created image capture instruction to the imaging device, and wherein the sensing signal reception module compares a signal level of the sensing signal with a reference value, sets a state value of the sensor corresponding to the sensing signal to the standby state when the signal level of the sensing signal is less than the reference value, and sets the state value of the sensor corresponding to the sensing signal to the sensing state when the signal level of the sensing signal is equal to or greater than the reference value. 2. The apparatus of claim 1 , wherein in any one time slot, only a single sensor has the sensing state as the state value thereof, or there is no sensor having the sensing state, among the multiple sensors included in the sensor unit. 3. The apparatus of claim 1 , wherein: the reference value is set for each of the multiple sensors, and the sensing signal reception module sets the state value of the sensor by comparing the signal level of the sensing signal with the reference value for the sensor corresponding to the sensing signal. 4. The apparatus of claim 1 , wherein when the state value of a first sensor, corresponding to a position at which the material is cut, changes from the standby state to the sensing state, the operational state control module initializes an operational state of the first sensor to an inactive state and sets the operational states of the other sensors, excluding the first sensor, to an image capture preparation state. 5. The apparatus of claim 4 , wherein when the state value of a second sensor in the image capture preparation state is the sensing state, the image capture instruction is created, and an operational state of the second sensor is initialized to the inactive state. 6. The apparatus of claim 1 , wherein the signal generation unit outputs the signal while moving so as to correspond to movement of a blade of the cutting device or movement of the material to be cut. 7. The apparatus of claim 1 , further comprising: an external input unit for receiving at least one of a number of the sensors included in the sensor unit, identifiers of the sensors, reference values for the respective sensors, and an instruction for initializing an operational state of the sensors. 8. The apparatus of claim 1 , wherein the material is cut by being moved up and down so as to correspond to a spindle that moves up and down according to rotation of a worm gear. 9. A method for controlling capture of an image of a cut surface, performed by an apparatus for controlling capture of an image of a cut surface of material, comprising: outputting a signal in an area within which a cutting device for cutting the material moves; sensing the output signal using multiple sensors and generating a sensing signal; and controlling an image-capturing operation of an imaging device, which captures the image of the cut surface, using the sensing signal, wherein each of the multiple sensors are configured to change from a standby state to a sensing state, wherein controlling the image-capturing operation of the imaging device comprises: setting a state value of the sensor using the sensing signal; creating an image capture instruction using the state value of the sensor; and transmitting the created image capture instruction to the imaging device, and wherein setting the state value of the sensor comprises: comparing a signal level of the sensing signal with a reference value; and setting the state value of the sensor corresponding to the sensing signal to the standby state when the signal level of the sensing signal is less than the reference value, and setting the state value of the sensor corresponding to the sensing signal to the sensing state when the signal level of the sensing signal is equal to or greater than the reference value. 10. The method of claim 9 , wherein in any one time slot, only a single sensor has the sensing state as the state value thereof, or there is no sensor having the sensing state, among the multiple sensors. 11. The method of claim 9 , wherein: the reference value is set for each of the multiple sensors, and setting the state value of the sensor is configured to set the state value of the sensor by comparing the signal level of the sensing signal with the reference value for the sensor corresponding to the sensing signal. 12. The method of claim 9 , wherein creating the image capture instruction comprises: when the state value of a first sensor, corresponding to a position at which the material is cut, changes from the standby state to the sensing state, initializing an operational state of the first sensor to an inactive state; and setting the operational states of the other sensors, excluding the first sensor, to an image capture preparation state. 13. The method of claim 12 , wherein when the state value of a second sensor in the image capture preparation state is the sensing state, the image capture instruction is created, and an operational state of the second sensor is initialized to the inactive state. 14. The method of claim 9 , wherein outputting the signal is configured such that the signal is output at a position corresponding to movement of a blade of the cutting device or movement of the material to be cut. 15. The method of claim 9 , further comprising: receiving at least one of a number of the sensors for sensing the signal, identifiers of the sensors, reference values for the respective sensors, and an instruction for initializing an operational state of the sensors. 16. The method of claim 9 , wherein the material is cut by being moved up and down so as to correspond to a spindle that moves up and down according to rotation of a worm gear.