Three-dimensional measuring device and three-dimensional measuring method

What is claimed is: 1. A three-dimensional measuring device using a time of flight (TOF) method, comprising: a light source unit configured to emit light at timing indicated by a light emission control signal and to be able to adjust for each of at least two irradiation regions an amount of light to be emitted; a light receiving unit configured to be exposed to light from a region including a target object at timing indicated by an exposure control signal and to produce three-dimensional information from a total exposure amount; an image processing unit configured to generate a distance image based on the three-dimensional information received from the light receiving unit; and a control unit configured to output the light emission control signal, the exposure control signal, and a region light amount signal indicating a radiation pattern as setting of the amount of light to be emitted to each of the irradiation regions, wherein the light source unit emits light according to the radiation pattern indicated by the region light amount signal, and the control unit outputs as the region light amount signal a signal that shows in chronological order a first radiation pattern in which the amount of light to be emitted to each of the irradiation regions is set to a predetermined basic amount of light, and a second radiation pattern in which the amount of light to be emitted to a first irradiation region as at least one of the irradiation regions is different from the predetermined basic amount of light. 2. The three-dimensional measuring device of claim 1 , wherein the second radiation pattern includes two or more kinds of radiation patterns that are different from each other. 3. The three-dimensional measuring device of claim 1 , wherein the image processing unit calculates a reflected light component of the amount of light emitted to the first irradiation region from the three-dimensional information according to the first radiation pattern and the three-dimensional information according to the second radiation pattern, and corrects the three-dimensional information by using the reflected light component. 4. The three-dimensional measuring device of claim 3 , wherein when the calculated reflected light component is larger than a predetermined value, the image processing unit sends the control unit a command to reduce the amount of light for the first irradiation region in the first and second radiation patterns. 5. The three-dimensional measuring device of claim 1 , wherein the light receiving unit produces two-dimensional RGB information in addition to the three-dimensional information, and the image processing unit generates the distance image and a two-dimensional color image based on the three-dimensional information and the RGB information which are received from the light receiving unit. 6. The three-dimensional measuring device of claim 5 , wherein the image processing unit detects a region where the target object is present from the RGB information and outputs a detection region signal indicating the detected region, and the control unit receives the detection region signal and sets the region light amount signal so as to reduce the amount of light for the irradiation region that does not include the region indicated by the detection region signal. 7. The three-dimensional measuring device of claim 1 , wherein the image processing unit outputs a detection signal to the control unit if there is a region in the distance image where a distance is equal to or smaller than a predetermined value, and the control unit sets the region light amount signal so as to set the amount of light for each of the irradiation regions to a prescribed basic amount of light when it receives the detection signal and to set the amount of light for at least one of the irradiation regions to a value smaller than the predetermined basic amount of light when it does not receive the detection signal. 8. The three-dimensional measuring device of claim 7 , wherein the control unit sets the amount of light for the at least one of the irradiation regions to zero when it does not receive the detection signal. 9. A three-dimensional measuring device using a time of flight (TOF) method, comprising: a light source unit configured to emit light at timing indicated by a light emission control signal and to be able to adjust for each of at least two irradiation regions an amount of light to be emitted; a light receiving unit configured to be exposed to light from a region including a target object at timing indicated by an exposure control signal and to produce three-dimensional information from a total exposure amount; an image processing unit configured to generate a distance image based on the three-dimensional information received from the light receiving unit; and a control unit configured to output the light emission control signal, the exposure control signal, and a region light amount signal indicating a radiation pattern as setting of the amount of light to be emitted to each of the irradiation regions, wherein the light source unit emits light according to the radiation pattern indicated by the region light amount signal, the light receiving unit produces two-dimensional RGB information in addition to the three-dimensional information, the image processing unit generates the distance image and a two-dimensional color image based on the three-dimensional information and the RGB information which are received from the light receiving unit, the three-dimensional measuring device has a predetermined color array pattern on its surface located on a light emitting side, the image processing unit recognizes that there is a mirror from the RGB information by performing pattern recognition of the color array pattern and outputs a mirror region signal indicating a region where the mirror is present, and the control unit receives the mirror region signal and sets the region light amount signal so as to reduce the amount of light for the irradiation region that includes the region indicated by the mirror region signal. 10. The three-dimensional measuring device of claim 9 , wherein the image processing unit calculates a distance to the mirror from a size of the region where the mirror is present in a plane represented by the RGB information. 11. A three-dimensional measuring method using a time of flight (TOF) method, the method using a light source unit configured to emit light at timing indicated by a light emission control signal and to be able to adjust for each of at least two irradiation regions an amount of light to be emitted, a light receiving unit configured to be exposed to light from a region including a target object at timing indicated by an exposure control signal and to produce three-dimensional information from a total exposure amount, and an image processing unit configured to generate a distance image based on the three-dimensional information received from the light receiving unit, the method comprising steps of: by the light emitting unit, emitting light according to a first radiation pattern in which the amount of light to be emitted to each of the irradiation regions is set to a predetermined basic amount of light; by the light emitting unit, emitting light according to a second radiation pattern in which the amount of light to be emitted to a first irradiation region as at least one of the irradiation regions is different from the predetermined basic amount of light; and by the image processing unit, calculating a reflected light component of the amount of light emitted to the first irradiation region from the three-dimensional information according to the first radiation pattern and th