Identification of variations or defects in a slab material, made from a continuous casting process

The invention claimed is: 1. A method for detecting defects in a manufacturing process, comprising: moving a material past an equipment structure, wherein a plurality of sensors is positioned in said equipment structure and is configured to detect a local physical property, and wherein at least two sensors of said plurality of sensors are oriented in a direction of movement of said material; receiving, by an electronic device, data of said local physical properties from said plurality of sensors; determining, by said electronic device at each location and time in said equipment structure, a difference between said data of said local physical properties and standard data, which corresponds to data where no defects in said material are expected; determining, by said electronic device, an accumulated difference for each location on said material over a time period based on said difference between said data of said local physical properties and said standard data; and displaying, by a display unit, a defect criterion of said accumulated difference at each location on said material for an operator to take corrective action, inspect and downgrade said material at locations having large magnitudes of said accumulated difference, and/or for forensic evaluation to investigate defects. 2. The method of claim 1 , wherein said equipment structure is a continuous casting mold, and said local physical property is temperature. 3. The method of claim 2 , wherein said plurality of sensors comprises one of thermocouples or Fiber Bragg Sensors embedded in copper walls or coating layers of said continuous casting mold. 4. The method of claim 1 , wherein said data of said local physical properties at an inner surface of said equipment structure is mapped to a surface of said material for an arbitrary speed history of a relative movement between said material and said equipment structure to determine said difference between said data of said local physical properties and said standard data. 5. The method of claim 1 , wherein said defect criterion is said accumulated difference integrated over said time period. 6. The method of claim 5 , wherein said accumulated difference is integrated over said time period by integrating a function associated with said accumulated difference over said time period. 7. The method of claim 5 , wherein said accumulated difference is integrated over said time period by dividing said accumulated difference by said time period in a Riemann sum approximation. 8. A method for determining an integrated physical property deviation at a single location in a process to manufacture a product, comprising: providing a first sensor and a second sensor in an instrumented region of a first material; moving a second material past said instrumented region of said first material, wherein said first sensor and said second sensor are each configured to detect a physical property, and said first sensor and said second sensor are aligned in a movement direction of said second material; detecting, by said first sensor at a first time, a first physical property of a first location of said first material that is proximate to a location on said second material when said second material is at a first position relative to said first material; determining, by an electronic device, a minimum of zero and a difference between said first physical property and a first standard physical property to provide a first physical property drop; detecting, by said second sensor at a second time, a second physical property of a second location of said first material that is proximate to said location on said second material when said second material is at a second position relative to said first material; determining, by said electronic device, a minimum of zero and a difference between said second physical property and a second standard physical property to provide a second physical property drop; and determining, by said electronic device, an integrated physical property deviation at said location on said second material based on said first physical property drop, said first time, said second physical property drop, and said second time. 9. The method of claim 8 , further comprising integrating, by said electronic device, a function associated with said first physical property drop and said second physical property drop between said first time and said second time to determine said integrated physical property deviation. 10. The method of claim 8 , further comprising: adding, by said electronic device, said first physical property drop and said second physical property drop to determine an aggregate property drop; and dividing, by said electronic device, said aggregate property drop by a difference between said first time and said second time to determine said integrated physical property deviation. 11. The method of claim 8 , wherein said first material defines a mold in a casting process, said second material is one of a metal, a plastic, or a fiberglass, and said second material moves past said mold in a continuous manufacturing process. 12. The method of claim 11 , wherein said first sensor and said second sensor are each temperature sensors, and said physical property is temperature. 13. The method of claim 8 , further comprising displaying, on a display unit, said integrated physical property deviation as said second material moves past said first material. 14. The method of claim 8 , further comprising moving said second material past said instrumented region of said first material according to an arbitrary speed history of a relative movement between said first material and said second material. 15. A system for determining an integrated temperature deviation in a manufacturing process, comprising: an equipment structure having a surface and an instrumented region positioned proximate to said surface; a material configured to move past said surface of said equipment structure in a movement direction; a first temperature sensor and a second temperature sensor positioned in said instrumented region of said equipment structure, wherein said first temperature sensor and said second temperature sensor are aligned in said movement direction; an electronic device operably connected to said first temperature sensor and to said second temperature sensor, and said electronic device having a non-transitory computer-readable medium comprising instructions executable by a processor to: receive a first temperature determined by a reading from said first temperature sensor at a first time, wherein said first temperature is at a first location of said equipment structure that is proximate to a location of said material when said material is at a first position relative to said equipment structure; determine a minimum of zero and a difference between said first temperature and a first standard temperature to provide a first temperature drop; receive a second temperature determined by a reading from said second temperature sensor at a second time, wherein said second temperature is at a second location of said equipment structure that is proximate to said location of said material when said material is at a second position relative to said equipment structure; determine a minimum of zero and a difference between said second temperature and a second standard temperature to provide a second temperature drop; and determine an integrated temperature deviation at said location on said material based on said first temperature drop, said first time, said second temperature drop, and said second time. 16. The system of claim 15