Composite laminate damage detection method using an in-situ thermal gradient and expansion differences across the damage

What is claimed is: 1. A system for in-situ inspection of a composite structure, the system comprising: a surface-strain imaging apparatus comprising a detector, the surface-strain imaging apparatus configured to image an area of an outer surface of the composite structure while a temperature of the composite structure warms to thermal equilibrium with a surrounding environment and a temperature gradient exists between an inner surface of the composite structure and the outer surface of the composite structure, wherein the inner surface of the composite structure and the outer surface of the composite structure are separated by multiple internal layers; a controller comprising a processor and memory, the controller configured to: detect, using data received from the surface-strain imaging apparatus, an out-of-plane displacement of the outer surface in the area caused by the temperature gradient, determine that a height of the out-of-plane displacement of the outer surface exceeds a threshold height, and based on determining that the height of the out-of-plane displacement exceeds the threshold height, flag the area of the outer surface for further inspection; and an output component, wherein flagging the area for further inspection comprises causing the output component to output a visual indication. 2. The system of claim 1 , wherein flagging the area of the outer surface for further inspection comprises highlighting a region corresponding to the area on a diagram of the composite structure. 3. The system of claim 1 , wherein the composite structure comprises an aircraft skin, and wherein the temperature gradient comprises a temperature difference of at least 20 degrees Celsius between an innermost layer of the aircraft skin and an outermost layer of the aircraft skin. 4. The system of claim 1 , wherein the surface-strain imaging apparatus comprises a shearography system. 5. The system of claim 1 , wherein the surface-strain imaging apparatus further comprises a light source and a retroreflective screen. 6. The system of claim 1 , wherein the surface-strain imaging apparatus comprises a three-dimensional (3D) scanner. 7. The system of claim 1 , wherein the surface-strain imaging apparatus is a handheld measurement instrument. 8. The system of claim 1 , further comprising a robotic crawler, wherein the surface-strain imaging apparatus is attached to the robotic crawler. 9. The system of claim 1 , further comprising an unmanned aerial vehicle (UAV), wherein the surface-strain imaging apparatus is attached to the UAV. 10. The system of claim 1 , wherein: the surface-strain imaging apparatus is configured to image the area of the outer surface from a first viewpoint, and the system further comprises another surface-strain imaging apparatus configured to image another area of the outer surface of the composite structure from a second viewpoint that is different from the first viewpoint. 11. A system for in-situ inspection of a composite structure, the system comprising: a surface-strain imaging apparatus comprising a detector, the surface-strain imaging apparatus configured to image an area of an outer surface of the composite structure while a temperature of the composite structure warms to thermal equilibrium with a surrounding environment and a temperature gradient exists between an inner surface of the composite structure and the outer surface of the composite structure, wherein the inner surface of the composite structure and the outer surface of the composite structure are separated by multiple internal layers; a controller comprising a processor and memory, the controller configured to: receive, from the surface-strain imaging apparatus, data indicative of a shape of the outer surface of the composite structure, and determine whether the data is indicative of a delamination between internal layers of the multiple internal layers of the composite structure, wherein determining whether the data is indicative of a delamination between internal layers of the composite structure comprises determining whether the data is indicative of an out-of-plane displacement having a height that exceeds a threshold height; and an output component configured to provide a visual indication of whether the data is indicative of a delamination between internal layers of the composite structure. 12. The system of claim 11 , wherein the composite structure comprises an aircraft skin, and wherein the temperature gradient comprises a temperature difference of at least 20 degrees Celsius between an innermost layer of the aircraft skin and an outermost layer of the aircraft skin. 13. The system of claim 11 , wherein the surface-strain imaging apparatus is a handheld measurement instrument. 14. The system of claim 11 , wherein: the surface-strain imaging apparatus is configured to image the area of the outer surface from a first viewpoint, and the system further comprises another surface-strain imaging apparatus configured to image another area of the outer surface of the composite structure from a second viewpoint that is different from the first viewpoint. 15. A method for in-situ inspection of a composite structure, the method comprising: imaging, using a surface-strain imaging apparatus, an area of an outer surface of the composite structure while a temperature of the composite structure warms to thermal equilibrium with a surrounding environment and a temperature gradient exists between an inner surface of the composite structure and the outer surface of the composite structure, wherein the inner surface of the composite structure and the outer surface of the composite structure are separated by multiple internal layers; detecting, by a controller using data received from the surface-strain imaging apparatus, an out-of-plane displacement of the outer surface in the area caused by the temperature gradient; determining, by the controller, that a height of the out-of-plane displacement exceeds a threshold height; and based on determining that the height of the out-of-plane displacement exceeds the threshold height, flagging, by the controller, the area of the outer surface for further inspection, wherein flagging the area of the outer surface for further inspection comprises causing an output component to output a visual indication. 16. The method of claim 15 , wherein flagging the area of the outer surface for further inspection comprises highlighting a region corresponding to the area on a diagram of the composite structure. 17. The method of claim 15 , wherein the composite structure comprises an aircraft skin, and wherein the temperature gradient comprises a temperature difference of at least 20 degrees Celsius between an innermost layer of the aircraft skin and an outermost layer of the aircraft skin. 18. The method of claim 15 , wherein the surface-strain imaging apparatus comprises a shearography system. 19. The method of claim 15 , wherein the surface-strain imaging apparatus further comprises a light source and a retroreflective screen. 20. The method of claim 15 , wherein the surface-strain imaging apparatus comprises a three-dimensional (3D) scanner.