Leak detection using reflection-based imaging

What is claimed is: 1 . A leak detection system comprising: an emitter configured to direct electromagnetic energy in a predetermined wavelength range toward a surface of a product, the product defining an enclosure chamber that contains a trace gas; a detector positioned between the emitter and the product at an offset distance from the surface of the product, wherein the detector is configured to detect reflected energy during leak testing of the product; and an electronic control unit (ECU) in communication with the detector, the ECU being configured to: receive an electronic input signal from the detector that is indicative of a spectrum of the reflected energy; identify a detected leak in the product, including comparing the spectrum of the reflected energy to a predetermined spectrum of the trace gas, wherein the trace gas has a wavelength that falls within the predetermined wavelength range of the electromagnetic energy from the emitter; and generate an output signal in response to the detected leak, the output signal identifying a presence and location of the leak. 2 . The leak detection system of claim 1 , wherein the emitter includes an infrared (IR) emitter. 3 . The leak detection system of claim 2 , wherein the predetermined wavelength range of the electromagnetic energy is about 2 microns (μ) to about 10μ. 4 . The leak detection system of claim 1 , wherein the offset distance from the surface of the product is about 0.25 meters (m) to about 5 m. 5 . The leak detection system of claim 1 , wherein the detector includes a filter having a bandwidth encompassing the wavelength of the trace gas and the predetermined wavelength range of the electromagnetic energy from the emitter. 6 . The leak detection system of claim 1 , wherein the ECU is configured to detect the presence and location of the leak by analyzing a difference in contrast between the spectrum of the reflected energy and the predetermined spectrum of the trace gas. 7 . The leak detection system of claim 1 , wherein the detector includes an array of detectors positioned in proximity to the product, and wherein each respective detector of the array of detectors is configured to detect the reflected energy from a different angle. 8 . The leak detection system of claim 1 , wherein the emitter is configured to move with respect to the product. 9 . The leak detection system of claim 1 , further comprising: a robot, wherein the detector is connected to the robot, and wherein the robot is configured to move the detector with respect to the product. 10 . The leak detection system of claim 9 , further comprising: a gantry configured to position the emitter relative to the product. 11 . The leak detection system of claim 1 , further comprising: a three-dimensional (3D) laser scanner configured to: scan the surface of the product; output a 3D scan file to the ECU that is indicative of a contour of the surface; compare the contour of the surface to a calibrated baseline contour to ascertain a surface distortion level of the product; and generate the electronic output signal using the surface distortion level. 12 . A leak detection method comprising: directing electromagnetic energy in a predetermined wavelength range, via an emitter, toward a surface of a product defining an enclosure chamber that contains a trace gas; detecting reflected energy via a detector that is positioned between the emitter and the product at an offset distance from the surface of the product; receiving an electronic input signal from the detector via an electronic control unit (ECU), wherein the electronic input signal is indicative of a spectrum of the reflected energy; identifying a detected leak in the product, via the ECU, including comparing the spectrum of the reflected energy to a predetermined spectrum of the trace gas, the trace gas having a wavelength that falls within the predetermined wavelength range of the electromagnetic energy from the emitter; and generating an electronic output signal in response to the detected leak, the output signal identifying a presence and location of the leak. 13 . The leak detection method of claim 12 , wherein: the emitter includes an infrared (IR) emitter; and directing the electromagnetic energy in the predetermined wavelength range includes directing IR energy having a wavelength in a range of about 750 nanometers (nm) to about 10 micrometer (μ). 14 . The leak detection method of claim 13 , wherein: the trace gas includes carbon dioxide; and directing the IR energy having the wavelength in the range of about 750 nm to about 10μ includes directing IR energy having a wavelength range of about 2μ to about 10μ. 15 . The leak detection method of claim 13 , wherein the offset distance from the surface of the product is about 0.25 meters (m) to about 5 m. 16 . The leak detection method of claim 12 , wherein directing the electromagnetic energy in the predetermined wavelength range includes directing the electromagnetic energy toward a vehicle component. 17 . The leak detection method of claim 12 , wherein identifying the detected leak includes analyzing a difference in contrast between the spectrum of the reflected electromagnetic energy and the predetermined spectrum of the trace gas. 18 . The leak detection method of claim 12 , further comprising: scanning the surface of the product using a three-dimensional (3D) laser scanner; outputting a 3D scan file to the ECU via the 3D laser scanner, the 3D scan file being indicative of a contour of the surface; comparing the contour of the surface to a calibrated baseline contour to ascertain a surface distortion level of the product; and generating the inspection output signal using the surface distortion level. 19 . A leak detection system, comprising: an infrared (IR) emitter array configured to direct IR energy toward a surface of a product in a wavelength range of about 2 microns (μ) to about 10μ, the product defining an enclosure chamber that contains carbon dioxide as a trace gas; an IR detector array positioned between the IR emitter array and the product at an offset distance of less than about 5 meters (m) from the surface of the product, wherein the IR detector array is configured to detect reflected IR energy during leak testing of the product; a three-dimensional (3D) laser scanner; and an electronic control unit in communication with the IR detector array, the ECU being configured to: receive an electronic input signal from the IR detector array that is indicative of a spectrum of the reflected IR energy; command the 3D laser scanner to generate a 3D scan file indicative of a contour of the surface; compare the contour of the surface to a calibrated baseline contour to ascertain a surface distortion level of the product; identify a detected leak in the product using the surface distortion and by comparing the spectrum of the reflected IR energy to a predetermined spectrum of the trace gas; and generate an electronic output signal in response to the detected leak, the electronic output signal identifying a presence and location of the leak. 20 . The leak detection system of claim 19 , further comprising: a robot configured to move the IR detector array with respect to the product; and a gantry configured to position the IR emitter array and the 3D laser scanner relative to the product.