DAS-based downhole tool orientation determination

The invention claimed is: 1. A downhole tool orientation determination system to determine a radial orientation of a tool conveyed downhole into a pipe via a carrier, the system comprising: an orientation tool conveyed downhole by the carrier that conveys the tool; and a distributed acoustic sensor (DAS) comprising an optical fiber disposed axially along an outer surface of the pipe; and a processor configured to determine a rotational position of the orientation tool with respect to the optical fiber based on measurements by the optical fiber at different rotational positions of the orientation tool, wherein the processor determines the radial orientation of the tool with respect to the optical fiber based on the rotational position of the orientation tool with respect to the optical fiber based on a fixed rotational relationship between the tool and the orientation tool, wherein the orientation tool includes a first transducer and the processor determines that the first transducer is at a closest position to the optical fiber among different positions of the first transducer based on the different rotational positions of the orientation tool when a phase delay between a measurement by the DAS and excitation by the first transducer is a lowest phase delay value among phase delay values obtained for the different rotational positions of the orientation tool, wherein operation of the tool is controlled based on the radial orientation determined by the processor. 2. The system according to claim 1 , wherein the orientation tool includes the first transducer and the system further comprises an impedance matched dampening element arranged to prevent a standing wave in the pipe based on excitation by the first transducer. 3. The system according to claim 2 , wherein the processor determines the rotational position of the orientation tool with respect to the optical fiber based on determining a phase delay between an excitation of the first transducer and the measurements by the optical fiber at the different rotational positions of the orientation tool. 4. The system according to claim 1 , wherein the orientation tool includes the first transducer and the processor determines the orientation of the first transducer of the orientation tool with respect to the optical fiber based on beam forming techniques. 5. The system according to claim 1 , wherein the orientation tool includes the first transducer and the system further comprises additional transducers arranged radially on the orientation tool and in contact with the pipe. 6. The system according to claim 5 , wherein the measurements by the optical fiber at the different rotational positions of the orientation tool is a response based on vibration excitation generated by the first transducer and the additional transducers, the first transducer providing greater vibration excitation than the additional transducers. 7. The system according to claim 6 , wherein the processor determines that the first transducer is at a closest position to the optical fiber among different positions of the first transducer based on the different rotational positions of the orientation tool when the response is a maximum response value obtained for the different rotational positions of the orientation tool. 8. The system according to claim 1 , wherein the processor determines the radial orientation of the tool with respect to the optical fiber based on the orientation tool being physically attached to the tool. 9. The system according to claim 1 , further comprising a compass to each of the orientation tool and the tool to determine the orientation of the orientation tool and the orientation of the tool with respect to magnetic north, wherein the processor determines the radial orientation of the tool with respect to the optical fiber based on determining a position of the optical fiber with respect to the magnetic north which is determined based on the orientation tool. 10. A method of determining a radial orientation of a tool conveyed downhole into a pipe via a carrier, the method comprising: conveying an orientation tool downhole via the carrier that conveys the tool; disposing an optical fiber axially along an outer surface of the pipe, the optical fiber being a measurement portion of a distributed acoustic sensor (DAS); processing, by a processor, measurements by the optical fiber at different rotational positions of the orientation tool to determine a rotational position of the orientation tool with respect to the optical fiber; determining the radial orientation of the tool with respect to the optical fiber based on the orientation of the orientation tool with respect to the optical fiber based on a fixed rotational relationship between the tool and the orientation tool, wherein the orientation tool includes a first transducer or a heating element in contact with an inner surface of the pipe, wherein the determining the radial orientation of the tool with respect to the optical fiber based on the rotational position of the orientation tool with respect to the optical fiber includes determining that the first transducer is at a closest position among different positions of the first transducer based on the different rotational positions of the orientation tool to the optical fiber when a phase delay between a measurement by the DAS and excitation by the first transducer is a lowest phase delay value among phase delay values obtained for the different rotational positions of the orientation tool; and controlling an operation of the tool based on the radial orientation of the tool. 11. The method according to claim 10 , wherein the orientation tool includes the first transducer and an impedance matched dampening element to prevent a standing wave in the pipe based on excitation by the first transducer, and the processing the measurements includes determining a phase delay between the excitation by the first transducer and the measurements by the optical fiber at the different rotational positions of the orientation tool. 12. The method according to claim 10 , wherein the orientation tool includes the first transducer and the determining the radial orientation of the tool with respect to the optical fiber based on the rotational position of the orientation tool with respect to the optical fiber includes determining the orientation of the first transducer of the orientation tool with respect to the optical fiber based on beam forming techniques. 13. The method according to claim 10 , wherein the orientation tool includes the first transducer and additional transducers arranged radially on the orientation tool and in contact with the pipe, the processing the measurements includes processing a response based on vibration excitation generated by the first transducer and the additional transducers, the first transducer providing greater vibration excitation than the additional transducers, and determining the rotational position of the orientation tool includes determining that the first transducer is at a closest position to the optical fiber among different positions of the first transducer based on the different rotational positions of the orientation tool when the response is a maximum response value obtained for the different rotational positions of the orientation tool. 14. The method according to claim 10 , wherein the determining the radial orientation of the tool with respect to the optical fiber is based on the orientation tool being physically attached to the tool or on a knowledge of the orientation of the orientation tool and the orientation of the tool with respect to magnetic north such that the determining