Abstract: A system for scanning an object 112 is provided. The system includes a continuous conveyor belt 102, a first electromagnetic radiation sensor 104, a second electromagnetic radiation sensor, a tunnel 106, an electromagnetic radiation generator 108, a third electromagnetic radiation sensor, a fourth electromagnetic radiation sensor 110 and a processor. The continuous conveyor belt 102 receives the object 112 and moves the object 112 in forward direction. The first electromagnetic radiation sensor scans the object 112 that is travelling through the continuous conveyor belt 102. The tunnel 106 receives the object 112 from the continuous conveyor belt 102 after scanned through the first electromagnetic radiation sensor 104. The second electromagnetic radiation sensor is positioned inside the tunnel 106 at entry point. The electromagnetic radiation generator 108 receives a second signal from the second electromagnetic radiation sensor to generate an angular beam of electromagnetic radiation on the object 112.

Abstract: A system for scanning an object 112 is provided. The system includes a continuous conveyor belt 102, a first electromagnetic radiation sensor 104, a second electromagnetic radiation sensor, a tunnel 106, an electromagnetic radiation generator 108, a third electromagnetic radiation sensor, a fourth electromagnetic radiation sensor 110 and a processor. The continuous conveyor belt 102 receives the object 112 and moves the object 112 in forward direction. The first electromagnetic radiation sensor scans the object 112 that is travelling through the continuous conveyor belt 102. The tunnel 106 receives the object 112 from the continuous conveyor belt 102 after scanned through the first electromagnetic radiation sensor 104. The second electromagnetic radiation sensor is positioned inside the tunnel 106 at entry point. The electromagnetic radiation generator 108 receives a second signal from the second electromagnetic radiation sensor to generate an angular beam of electromagnetic radiation on the object 112.

Abstract: An explosive detection system for detecting explosive trace in a sample includes a detection unit, and a processing unit. The detection unit that receives a desorbed sample includes a first heater, a second heater, a first resistance temperature detector (RTD), a second RTD, and an amplifier. The first heater is exposed to the desorbed sample. The first heater and the second heater are supplied with specific voltage for three or more experiments. The first RTD and the second RTD measure changes in resistance due to heating of the first heater and the second heater to calculate voltages across the first RTD and the second RTD. The amplifier amplifies the voltages to calculate a differential voltage for each of the three or more experiments, and converts the differential voltage into a digital signal. The processing unit is configured to process the digital signal to detect explosive trace in the desorbed sample.

Abstract: An under vehicle scanning system that detects a dissimilar object in a vehicle is provided. The under vehicle scanning system includes a scanner and acquisition module that captures 3D images of an undercarriage of the vehicle at multiple instants, an analysis and processing module that processes the 3D images to obtain 3D profiles of the vehicle, and a display module that highlights the dissimilar object. The analysis and processing module is configured to: (a) normalize variations in orientation of the 3D profiles of the vehicle's undercarriage, (b) generate a 3D signature of the vehicle based on the normalized 3D profiles of the vehicle's undercarriage, (c) identify a model of the vehicle based on the 3D signature of the vehicle, and (d) compare the 3D profiles of the vehicle with a standard profile of the undercarriage of a same model vehicle using the 3D signature to detect the dissimilar object.

Abstract: An asymmetric immobilization process that immobilizes a one or more receptor biomolecules on one or more solid surfaces is provided. The asymmetric immobilization process includes the following steps: (i) activating the one or more solid surfaces using an oxidizing agent; (ii) treating the one or more solid surfaces with aminosilane to obtain a one or more amine functionalized solid surfaces; (iii) treating the one or more receptor biomolecules with a 1-Ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) to obtain a one or more site-specific EDC activated receptor biomolecules; and (iv) immobilizing the one or more site-specific EDC activated receptor biomolecules on a first layer of the one or more amine functionalized solid surfaces, wherein the immobilizing comprises treating the one or more site-specific EDC activated receptor biomolecules with amine groups of the first layer of the one or more amine functionalized solid surfaces to form a covalent amide bond.

Abstract: Various embodiments of the methods and systems disclosed herein provide a detection system that detects concentration of an analyte biomolecule (e.g., a protein, a biomarker, etc.) in a sample (e.g., a blood sample) to diagnose a disease. The detection system includes one or more micro-cantilevers that are immobilized with one or more receptor biomolecules to detect a concentration of an analyte biomolecule in the sample. The detection system further compares the concentration of the analyte biomolecule with a threshold value for diagnosing a disease.

Abstract: An asymmetric immobilization process that immobilizes a one or more receptor biomolecules on one or more solid surfaces is provided. The asymmetric immobilization process includes the following steps: (i) activating the one or more solid surfaces using an oxidizing agent; (ii) treating the one or more solid surfaces with aminosilane to obtain a one or more amine functionalized solid surfaces; (iii) treating the one or more receptor biomolecules with a 1-Ethyl-3-(3-dimethylaminopropyl)carbodiimide (EDC) to obtain a one or more site-specific EDC activated receptor biomolecules; and (iv) immobilizing the one or more site-specific EDC activated receptor biomolecules on a first layer of the one or more amine functionalized solid surfaces, wherein the immobilizing comprises treating the one or more site-specific EDC activated receptor biomolecules with amine groups of the first layer of the one or more amine functionalized solid surfaces to form a covalent amide bond.

Abstract: An under vehicle scanning system that detects a dissimilar object in a vehicle is provided. The under vehicle scanning system includes a scanner and acquisition module that captures 3D images of an undercarriage of the vehicle at multiple instants, an analysis and processing module that processes the 3D images to obtain 3D profiles of the vehicle, and a display module that highlights the dissimilar object. The analysis and processing module is configured to: (a) normalize variations in orientation of the 3D profiles of the vehicle's undercarriage, (b) generate a 3D signature of the vehicle based on the normalized 3D profiles of the vehicle's undercarriage, (c) identify a model of the vehicle based on the 3D signature of the vehicle, and (d) compare the 3D profiles of the vehicle with a standard profile of the undercarriage of a same model vehicle using the 3D signature to detect the dissimilar object.

Abstract: An explosive detection system for detecting explosive trace in a sample includes a detection unit, and a processing unit. The detection unit that receives a desorbed sample includes a first heater, a second heater, a first resistance temperature detector (RTD), a second RTD, and an amplifier. The first heater is exposed to the desorbed sample. The first heater and the second heater are supplied with specific voltage for three or more experiments. The first RTD and the second RTD measure changes in resistance due to heating of the first heater and the second heater to calculate voltages across the first RTD and the second RTD. The amplifier amplifies the voltages to calculate a differential voltage for each of the three or more experiments, and converts the differential voltage into a digital signal. The processing unit is configured to process the digital signal to detect explosive trace in the desorbed sample.