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The present invention provides an optical sensor for monitoring current or power in a monitored element of a device such as a bridge-wire or hot-wire of electro-explosive devices. The optical sensor comprises an optical sensor made of semiconductor material. The semiconductor material comprises an a

The present invention provides an optical sensor for monitoring current or power in a monitored element of a device such as a bridge-wire or hot-wire of electro-explosive devices. The optical sensor comprises an optical sensor made of semiconductor material. The semiconductor material comprises an absorption edge which is sensitive to a temperature variation. The semiconductor material is for placing in thermal contact with the monitored element of the device, whereby, when the current or power varies in the monitored element, it causes a variation in temperature in the semiconductor element and hence a spectral shift of the absorption edge which can be measured and which is representative of current and power variation.

대표청구항 ▼

We claim: 1. An optical sensor system for monitoring an electrical current or power in an element to be monitored, said optical sensor system comprising: an optical sensor having: a temperature sensitive element made of a semiconductor material having a transition in its optical absorption spectrum

We claim: 1. An optical sensor system for monitoring an electrical current or power in an element to be monitored, said optical sensor system comprising: an optical sensor having: a temperature sensitive element made of a semiconductor material having a transition in its optical absorption spectrum, a spectral position of said transition varying with temperature, said temperature sensitive element having a contact surface for being placed in thermal contact with a surface of a continuous portion of the element to be monitored; a distance between the temperature sensitive element and the surface of the continuous portion of the element to be monitored, thereby, ensuring that none of said electrical current or power in said element to be monitored is to flow within said optical sensor, whereby said temperature sensitive element is to sense a variation in temperature of the element to be monitored as caused by said electrical current or power; an optical fiber for guiding light to said optical sensor and for collecting light propagated in said optical sensor; a spectrophotometer for measuring an optical absorption spectrum of the propagated light; and a processing unit for determining said spectral position of said transition in the measured optical absorption spectrum, and for converting said spectral position into a measurement of said current or power. 2. The optical sensor system as claimed in claim 1, wherein said semiconductor material comprises a direct bandgap semiconductor material. 3. The optical sensor system as claimed in claim 1, wherein said semiconductor material comprises a silicon-based indirect bandgap semiconductor material. 4. The optical sensor system as claimed in claim 1, wherein said optical sensor has a light transmission surface, light entering said optical sensor from said light transmission surface being propagated in said temperature sensitive element and being reflected on said contact surface, back to said light transmission surface. 5. The optical sensor system as claimed in claim 1, wherein the distance is substantially occupied by a non-electrically conductive material on the contact surface of the temperature sensitive element. 6. The optical sensor system as claimed in claim 2, wherein said direct bandgap semiconductor material comprises an undoped gallium arsenide monocrystal. 7. The optical sensor system as claimed in claim 4, wherein said optical fiber has an end surface bonded to said light transmission surface. 8. The optical sensor system as claimed in claim 4, wherein said optical sensor has an antireflection coating on said light transmission surface. 9. The optical sensor system as claimed in claim 8, wherein said antireflection coating comprises a multilayer antireflection coating. 10. The optical sensor system as claimed in claim 5, wherein said optical sensor has a high reflection coating on said contact surface, between the temperature sensitive material and the non-electrically conductive material. 11. The optical sensor system as claimed in claim 10, wherein said high reflection coating comprises a multilayer high reflection coating. 12. The optical sensor system as claimed in claim 5, wherein the non-electrically conductive material comprises a thermally conductive adhesive. 13. An optical sensor system for monitoring an electrical current or power in a bridge-wire of an electro-explosive device, said optical sensor system comprising: a bridge-wire for installation in the electro-explosive device; an optical sensor having a temperature sensitive element made semiconductor material having a transition in its optical absorption spectrum, a spectral position of said transition varying with temperature, said temperature sensitive element having a contact surface placed in thermal contact with a surface of a continuous portion of the bridge-wire; a non-electrically conductive material on the contact surface of the temperature sensitive element, distancing the temperature sensitive element from the surface of the continuous portion of the bridge-wire, thereby ensuring that none of said electrical current or power in said bridge-wire is to flow within said optical sensor, whereby said temperature sensitive element senses a variation in temperature of the bridge-wire as caused by said electrical current or power; an optical fiber for guiding light to said optical sensor and for collecting light propagated in said optical sensor; a spectrophotometer for measuring an optical absorption spectrum of the propagated light; and a processing unit for determining said spectral position of said transition in the measured optical absorption spectrum, and for converting said spectral position into a measurement of said current or power in said bridge-wire. 14. The optical sensor system as claimed in claim 13, wherein said temperature sensitive element comprises a direct bandgap semiconductor material. 15. The optical sensor system as claimed in claim 13, wherein said optical sensor has a light transmission surface, light entering said optical sensor from said light transmission surface being propagated in said temperature sensitive element and being reflected on said contact surface, back to said light transmission surface. 16. The optical sensor system as claimed in claim 14, wherein said semiconductor material comprises an undoped gallium arsenide monocrystal. 17. The optical sensor system as claimed in claim 15, wherein said optical fiber has an end surface bonded to said light transmission surface. 18. A method for monitoring at least one of an electrical current and an electrical power in an element to be monitored, said method comprising: placing a contact surface of a temperature sensitive element in thermal contact with a surface of a continuous portion of the element to be monitored, and distanced from the surface of the continuous portion of the element to be monitored, a temperature of said monitored element being representative of said at least one of an electrical current and an electrical power in said monitored element; guiding light to said temperature sensitive element and collecting light propagated in said temperature sensitive element using an optical fiber; measuring an optical absorption spectrum of the propagated light; determining a spectral position of a transition in the measured optical absorption spectrum, said spectral position varying with said temperature of said monitored element; converting said spectral position into a measurement of said at least one of a current and a power using a known relation between said spectral position and said at least one of a current and a power; and outputting said measurement of said at least one of a current and a power. 19. The method as claimed in claim 18, further comprising: receiving light in said optical sensor from a first surface of said optical sensor; propagating the received light in said temperature sensitive element; reflecting the propagated light on said contact surface; and outputting the reflected light from said first surface.