Lidar using negative correlation

What is claimed is: 1 . A LIDAR using negative correlation signals, comprising: a correlation signal generation unit configured to generate two or more negative correlation signals; a signal transmission/reception unit configured to output a part of the two or more negative correlation signals to an atmosphere as a transmission signal, and receive a signal returned by reflecting from a target among the output transmission signals as a received signal; and a processing unit configured to confirm characteristics of the target using the received signal and a reference signal, wherein the remaining correlation signal of the two or more signals other than the transmission signal is used as the reference signal. 2 . A LIDAR using negative correlation signals, comprising: a correlation signal generation unit configured to generate two or more different negative correlation signals; a local oscillator configured to generate polarization components in two different directions, a signal transmission/reception unit configured to output a part of the two or more negative correlation signals to an atmosphere as a transmission signal, and receive a signal returned by reflecting from a target among the output transmission signals as a received signal; a first polarization beam splitter configured to divide the polarization components in two directions generated by the local oscillator into a polarization component in an X direction and a polarization component in a Y direction; a second polarization beam splitter configured to divide the received signal into a polarization component in the X direction and a polarization component in the Y direction; and a processing unit configured to confirm characteristics of the target using detection signals, which are detected from the polarization components in the X direction and the Y direction respectively divided by the first polarization beam splitter and the second polarization beam splitter, and a reference signal, wherein the remaining correlation signal of the two or more signals other than the transmission signal is used as the reference signal. 3 . The LIDAR according to claim 1 , further comprising a decision unit configured to determine whether the received signal and a delay reference signal obtained by delaying the reference signal for a predetermined time have a negative correlation with each other, wherein the decision unit determines that, when a signal obtained by adding the delay reference signal and the received signal together has a signal to noise ratio (SNR) higher than a predetermined magnitude, the delay reference signal and the received signal have a negative correlation with each other, and the processing unit confirms characteristics of the target using the delay time when the delay reference signal and the received signal have the negative correlation with each other. 4 . The LIDAR according to claim 2 , further comprising a decision unit configured to determine whether the detection signal and a delay reference signal obtained by delaying the reference signal for a predetermined time have a negative correlation with each other, wherein the decision unit determines that, when a signal obtained by adding the delay reference signal and the detection signal has an SNR higher than a predetermined magnitude, the delay reference signal and the detection signal have a negative correlation with each other, and the processing unit confirms the characteristics of the target using the delay time when the delay reference signal and the detection signal have the negative correlation with each other. 5 . The LIDAR according to claim 1 , wherein the correlation signal generation unit comprises: a light source, a first optical splitting unit configured to divide a light emitted from the light source into two or more lights having different wavelengths; an optical amplifier configured to amplify the divided two or more lights; a Fabry-Perot laser diode configured to receive the light amplified by the optical amplifier and introduced therein, and form two or more correlation signals having a negative correlation between intensities of the two or more lights using a strong gain saturation phenomenon; and a second optical splitting unit configured to divide the two or more correlation signals formed by the Fabry-Perot laser diode into the reference signal and the transmission signal. 6 . The LIDAR according to claim 2 , wherein the negative correlation signal generation unit comprises: a first light source and a second light source configured to respectively emit laser beams having two or more different wavelengths; a first signal source and a second signal source configured to generate signals for forming correlation signals; a first modulator and a second modulator configured to modulate intensities of the laser beam emitted from the first light source and the signal generated by the first signal source, and the laser beam emitted from the second light source and the signal generated by the second signal source; a negative correlation generator configured to generate a strong gain saturation in the lights modulated and introduced by the first modulator and the second modulator to generate the two or more correlation signals; and an optical splitting unit configured to divide the two Or more correlation signals generated by the negative correlation generator into the reference signal and the transmission signal. 7 . The LIDAR according to claim 6 , wherein any one modulator of the first modulator and the second modulator directly modulates the signal generated by any one signal source of the first signal source and the second signal source with respect to the laser beam emitted from the light source corresponding to any one modulator of the first light source and the second light source, and the other modulator modulates the signal generated by the corresponding signal source to a value of −1 times that of the signal source with respect to the laser beam emitted from the other light source, so as to form a negative correlation between the correlation signals of the two modes.