초록 ▼

In one or more embodiments, one or more systems, methods and/or processes may determine a location of a remote object (e.g., a point and/or area of interest, landmark, structure that “looks interesting”, buoy, anchored boat, etc.). For example, the location of a remote object may be determined via a

In one or more embodiments, one or more systems, methods and/or processes may determine a location of a remote object (e.g., a point and/or area of interest, landmark, structure that “looks interesting”, buoy, anchored boat, etc.). For example, the location of a remote object may be determined via a first bearing, at a first location, and a second bearing, at a second location, to the remote object. For instance, the first and second locations can be determined via a position device, such as a global positioning system device. In one or more embodiments, the location of the remote object may be based on the first location, the second location, the first bearing, and the second bearing. For example, the location of the remote object may be provided to a user via a map. For instance, turn-by-turn direction to the location of the remote object may be provided to the user.

대표청구항 ▼

1. A system, comprising: a position device;a processor;at least one camera; anda memory device, wherein the memory device stores instructions that are executable by the processor;wherein the position device: receives multiple location signals, via at least one antenna coupled to the position device;

1. A system, comprising: a position device;a processor;at least one camera; anda memory device, wherein the memory device stores instructions that are executable by the processor;wherein the position device: receives multiple location signals, via at least one antenna coupled to the position device; anddetermines a first position and a second position, different from the first position, via computing the first position, based on a first location of the at least one antenna and the multiple location signals, and computing the second position, based on a second location of the at least one antenna and the multiple location signals, wherein the second location of the at least one antenna is different from the first location of the at least one antenna;wherein the at least one camera: acquires a first image, as first machine-readable data, that includes a first remote object image of a remote object and that corresponds to the first position; andacquires a second image, as second machine-readable data, that includes a second remote object image of the remote object and that corresponds to the second position; andwherein, as the processor executes the instructions, the processor: determines, via the first machine-readable data, a first image position of the first remote object image of the remote object included by the first image;determines, via the first machine-readable data, a first bearing to the remote object at a remote object position, different from the first position and different from the second position, based on the first image position;determines, via the second machine-readable data, a second image position of the second remote object image of the remote object included by the second image;determines, via the second machine-readable data, a second bearing to the remote object at the remote object position based on the second image position;computes a first rotation, by the first bearing, of a first vector associated with the first position;computes a second rotation, by the second bearing, of a second vector associated with the second position;computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector. 2. The system of claim 1, wherein the processor further provides, via a display, information based on the remote object position. 3. The system of claim 1, wherein the processor further: receives first user input that indicates the first image position of the first remote object image of the remote object included by the first image; andreceives second user input that indicates the second image position of the second remote object image of the remote object included by the second image. 4. The system of claim 3, wherein the processor further displays, via a display, the first image and the second image. 5. The system of claim 1, wherein the first image position of the first remote object image of the remote object included by the first image is based on a first number of pixels;wherein the second image position of the second remote object image of the remote object included by the second image is based on a second number pixels;wherein when the processor determines the first bearing to the remote object at the remote object position, the processor utilizes the first number of pixels; andwherein when the processor determines the second bearing to the remote object at the remote object position via the second image position, the processor utilizes the second number of pixels. 6. The system of claim 5, wherein when the processor determines the first bearing to the remote object at the remote object position, utilizing the first number of pixels, the processor utilizes at least one of a first function of number of pixels to angles and a first mapping of number of pixels to angles; andwherein when the processor determines the second bearing to the remote object at the remote object position via the second image position, utilizing the second number of pixels, the processor utilizes at least one of a second function of number of pixels to angles and a second mapping of number of pixels to angles. 7. The system of claim 5, wherein the second number of pixels equals the first number of pixels. 8. The system of claim 5, wherein the at least one of the second function of number of pixels to angles and the second mapping of number of pixels to angles is the at least one of the first function of number of pixels to angles and the first number of mapping of pixels to angles. 9. The system of claim 1, wherein the at least one camera further acquires at least one of a motion picture and a video that includes the first image and the second image. 10. The system of claim 1, wherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes an intersection of a first plane and a second plane, different from the first plane;wherein the first plane includes the first position and the remote object position;wherein the second plane includes the second position and the remote object position; andwherein the intersection of the first plane and the second plane indicates the remote object position. 11. The system of claim 1, wherein the processor further: computes, utilizing the first position, a first plane, wherein the first plane is normal to the first vector and the first plane initially includes the first position, a geographic pole, and an origin; andcomputes, utilizing the second position, a second plane, wherein the second plane is normal to the second vector and the second plane initially includes the second position, the geographic pole, and the origin;wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor computes a rotation of the first plane about the first position by the first bearing such that the first plane no longer includes the geographic pole and includes the first position, the origin, and the remote object position;wherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor computes a rotation of the second plane about the second position by the second bearing such that the second plane no longer includes the geographic pole and includes the second position, the origin, and the remote object position; andwherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes an intersection of the first plane and the second plane. 12. The system of claim 1, wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor: computes a first quaternion, utilizing the first position and the first bearing;computes a second quaternion, utilizing the first vector;computes an inverse of the first quaternion as a third quaternion; andcomputes a first quaternion multiplication of the first quaternion, the second quaternion, and the third quaternion; andwherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor: computes a fourth quaternion, utilizing the second position and the second bearing;computes a fifth quaternion, utilizing the second vector;computes an inverse of the fourth quaternion as a sixth quaternion; andcomputes a second quaternion multiplication of the fourth quaternion, the fifth quaternion, and the sixth quaternion. 13. The system of claim 1, wherein the first rotation, by the first bearing, of the first vector is associated with a third vector;wherein the second rotation, by the second bearing, of the second vector is associated with a fourth vector; andwherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes a cross product of the third vector and the fourth vector, wherein the cross product indicates the remote object position. 14. The system of claim 13, wherein the processor further: computes, utilizing the first position, the first vector normal to the first position, an origin, and a geographic pole; andcomputes, utilizing the second position, the second vector normal to the second position, the origin, and the geographic pole;wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor computes a first transform of the first vector into the third vector, wherein the processor computes the first rotation of the first vector about the first position by the first bearing; andwherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor computes a second transform of the second vector into the fourth vector, wherein the processor computes the second rotation of the second vector about the second position by the second bearing. 15. The system of claim 1, further comprising: an electronic heading device;wherein the electronic heading device computes a first heading;wherein the electronic heading device computes a second heading;wherein when the processor determines the first bearing to the remote object at the remote object position based on the first image position, the processor determines the first bearing to the remote object at the remote object position further based on the first heading; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor determines the second bearing to the remote object at the remote object position further based on the second heading. 16. The system of claim 15, wherein the first heading includes the second heading. 17. The system of claim 15, wherein the position device includes the electronic heading device. 18. The system of claim 17, wherein the position device includes a global position system (GPS) receiver device that computes the first heading and computes the second heading. 19. The system of claim 1, further comprising: an electronic heading device;wherein the electronic heading device computes a first heading via a first transform of a magnetic field and a first orientation of the electronic bearing device within the magnetic field into a first machine readable signal based on the first heading;wherein the electronic heading device computes a second heading via a second transform of the magnetic field and a second orientation of the electronic bearing device within the magnetic field into a second machine readable signal based on the second heading;wherein when the processor determines the first bearing to the remote object at the remote object position based on the first image position, the processor determines the first bearing to the remote object at the remote object position further based on the first heading via the first machine readable signal; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor determines the second bearing to the remote object at the remote object position further based on the second heading via the second machine readable signal. 20. The system of claim 19, wherein the electronic heading device includes a plurality of magnetic field sensor devices;wherein the electronic heading device computes the first heading via the first transform of the magnetic field and the first orientation of the electronic heading device within the magnetic field into the first machine readable signal via the plurality of magnetic field sensor devices; andwherein the electronic heading device computes the second heading via the second transform of the magnetic field and the second orientation of the electronic heading device within the magnetic field into the second machine readable signal via the plurality of magnetic field sensor devices. 21. The system of claim 20, wherein the plurality of magnetic field sensor devices includes a plurality of magnetometers. 22. The system of claim 1, wherein when the position device determines the first position and the second position, different from the first position, via computing the first position, based on the first location of the at least one antenna and the multiple location signals, computing the second position, based on the second location of the at least one antenna and the multiple location signals, the position device: computes the first position while the at least one antenna is moving at a first speed; andcomputes the second position while the at least one antenna is moving at a second speed. 23. The system of claim 22, wherein the second speed is the first speed. 24. The system of claim 1, wherein the position device further provides the first position and the second position to the processor;wherein the at least one camera further provides the first image and the second image to the processor; andwherein the processor further: receives the first position and the second position from the position device; andreceives the first image and the second image from the at least one camera. 25. The system of claim 1, wherein the processor further receives multiple data sets;wherein a first data set of the multiple data sets includes the first image and the first position; andwherein a second data set of the multiple data sets includes the second image and the second position. 26. The system of claim 1, wherein the position device includes a global position system (GPS) receiver device. 27. The system of claim 1, further comprising: the display;wherein the display is coupled to the processor; andwherein the display displays the information based on the remote object position. 28. The system of claim 1, further comprising: the at least one antenna. 29. The system of claim 1, wherein when the processor determines the first bearing to the remote object at the remote object position, different from the first position and different from the second position, based on the first image position, the processor performs at least one of adding a declination angle and subtracting the declination angle; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor performs at least one of adding the declination angle and subtracting the declination angle. 30. The system of claim 1, wherein the at least one camera includes at least two cameras;wherein when the at least one camera acquires the first image that includes the first remote object image of the remote object and that corresponds to the first position, a first camera of the at least two cameras acquires the first image that includes the first remote object image of the remote object and that corresponds to the first position; andwherein when the at least one camera acquires the second image that includes the second remote object image of the remote object and that corresponds to the second position, a second camera of the at least two cameras acquires the second image that includes the second remote object image of the remote object and that corresponds to the second position. 31. The system of claim 30, wherein a first center of view of the first camera is different from a second center of view of the second camera. 32. The system of claim 1, wherein the at least one camera acquires the first image that includes the first remote object image and that corresponds to the first position while moving at a first speed; andwherein the at least one camera acquires the second image that includes the second remote object image and that corresponds to the second position while moving at a second speed. 33. The system of claim 32, wherein the second speed is the first speed. 34. A method, comprising: a position device, coupled to at least one antenna, receiving multiple location signals via the at least one antenna;the position device computing a first position and a second position, different from the first position, based on the multiple location signals and a first location of the at least one antenna and a second location, different from the first location, of the at least one antenna;at least one camera acquiring a first image, as first machine-readable data that includes a first remote object image of a remote object and that corresponds to the first position;the at least one camera acquiring a second image, as second machine-readable data, that includes a second remote object image of the remote object and that corresponds to the second position;a processor determining, via the first machine-readable data, a first image position of the first remote object image of the remote object included by the first image;the processor determining, via the first machine-readable data, a first bearing to the remote object at a remote object position, different from the first position and different from the second position, based on the first image position;the processor determining, via the second machine-readable data, a second image position of the second remote object image of the remote object included by the second image;the processor determining, via the second machine-readable data, a second bearing to the remote object at the remote object position based on the second image position;the processor computing a first rotation, by the first bearing, of a first vector associated with the first position;the processor computing a second rotation, by the second bearing, of a second vector associated with the second position; andthe processor computing the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector. 35. The method of claim 34, further comprising: the processor providing, via a display, information based on the remote object position. 36. The method of claim 34, further comprising: the processor receiving first user input that indicates the first image position of the first remote object image of the remote object included by the first image; andthe processor receiving second user input that indicates the second image position of the second remote object image of the remote object included by the second image. 37. The method of claim 36, further comprising: the processor providing, via a display, the first image and the second image. 38. The method of claim 36, wherein the first image position of the first remote object image of the remote object included by the first image is based on a first number of pixels;wherein the second image position of the second remote object image of the remote object included by the second image is based on a second number of pixels;wherein the processor determining the first bearing to the remote object at the remote object position, different from the first position and different from the second position, based on the first image position includes utilizing the first number of pixels; andwherein the processor determining the second bearing to the remote object at the remote object position based on the second image position includes utilizing the second number of pixels. 39. The method of claim 38, wherein the processor determining the first bearing to the remote object at the remote object position, different from the first position and different from the second position, based on the first image position further includes utilizing at least one of a first function of number of pixels to angles and a first mapping of number of pixels to angles; andwherein the processor determining the second bearing to the remote object at the remote object position based on the second image position further includes utilizing at least one of a second function of number of pixels to angles and a second mapping of number of pixels to angles. 40. The method of claim 38, wherein the second number of pixels equals the first number of pixels. 41. The method of claim 38, wherein the at least one of the second function of number of pixels to angles and the second mapping of number of pixels to angles is the at least one of the first function of number of pixels to angles and the first mapping of number of pixels to angles. 42. The method of claim 34, wherein the processor computing the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector includes computing an intersection of a first plane and a second plane, different from the first plane;wherein the first plane includes the first position and the remote object position;wherein the second plane includes the second position and the remote object position; andwherein the intersection of the first plane and the second plane indicates the remote object position. 43. The method of claim 42, wherein the processor computing the intersection of the first plane and the second plane includes computing a cross product of a third vector associated with the first plane and a fourth vector, different from the third vector, associated with the second plane. 44. The method of claim 34, further comprising: the processor computing, utilizing the first position, a first plane, wherein the first plane is normal to the first vector and the first plane initially includes the first position, a geographic pole, and an origin; andthe processor computing, utilizing the second position, a second plane, wherein the second plane is normal to the second vector and the second plane initially includes the second position, the geographic pole, and the origin;wherein the computing the first rotation, by the first bearing, of the first vector associated with the first position includes computing a rotation of the first plane about the first position by the first bearing such that the first plane no longer includes the geographic pole and includes the first position, the origin, and the remote object position;wherein the processor computing the second rotation, by the second bearing, of the second vector associated with the second position includes computing a rotation of the second plane about the second position by the second bearing such that the second plane no longer includes the geographic pole and includes the second position, the origin, and the remote object position; andwherein the processor computing the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector includes computing an intersection of the first plane and the second plane. 45. The method of claim 34, wherein the processor computing the first rotation, by the first bearing, of the first vector associated with the first position includes utilizing a first rotation matrix based on the first position and the first bearing; andwherein the processor computing the second rotation, by the second bearing, of the second vector associated with the second position includes utilizing a second rotation matrix based on the second position and the second bearing. 46. The method of claim 34, wherein the processor computing the first rotation, by the first bearing, of the first vector associated with the first position includes: computing a first quaternion, utilizing the first position and the first bearing;computing a second quaternion, utilizing the first vector;computing an inverse of the first quaternion as a third quaternion; andcomputing a first quaternion multiplication of the first quaternion, the second quaternion, and the third quaternion; andwherein the processor computing the second rotation, by the second bearing, of the second vector associated with the second position includes: computing a fourth quaternion, utilizing the second position and the second bearing;computing a fifth quaternion, utilizing the second vector;computing an inverse of the fourth quaternion as a sixth quaternion; andcomputing a second quaternion multiplication of the fourth quaternion, the fifth quaternion, and the sixth quaternion. 47. The method of claim 34, wherein the first rotation, by the first bearing, of the first vector is associated with a third vector;wherein the second rotation, by the second bearing, of the second vector is associated with a fourth vector;wherein the processor computing the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector includes computing a cross product of the third vector and the fourth vector; andwherein the cross product indicates the remote object position. 48. The method of claim 47, further comprising: the processor computing, utilizing the first position, the first vector normal to the first position, an origin, and a geographic pole; andthe processor computing, utilizing the second position, the second vector normal to the second position, the origin, and the geographic pole;wherein the processor computing the first rotation, by the first bearing, of the first vector associated with the first position includes computing a first transform of the first vector into the third vector via computing the first rotation of the first vector about the first position by the first bearing; andwherein the processor computing the second rotation, by the second bearing, of the second vector associated with the second position includes computing a second transform of the second vector into the fourth vector via computing the second rotation of the second vector about the second position by the second bearing. 49. The method of claim 34, further comprising: the at least one camera acquiring at least one of a motion picture and a video that includes the first image and the second image. 50. The method of claim 34, wherein the position device receiving multiple location signals via the at least one antenna includes receiving a first portion of the multiple location signals via the at least one antenna at the first location and receiving a second portion of the multiple location signals via the at least one antenna at the second location; andwherein the position device computing the first position and the second position, different from the first position, based on the multiple location signals and the first location of the at least one antenna and the second location, different from the first location, of the at least one antenna includes: computing the first location of the at least one antenna via the first portion of the multiple location signals; andcomputing the second location of the at least one antenna via the second portion of the multiple location signals. 51. The method of claim 50, wherein said receiving the first portion of the multiple location signals via the at least one antenna at the first location occurs while the at least one antenna is moving at a first speed; andwherein said receiving the second portion of the multiple location signals via the at least one antenna at the second location occurs while the at least one antenna is moving at a second speed. 52. The method of claim 51, wherein the second speed is the first speed. 53. The method of claim 34, wherein the position device includes a global position system (GPS) receiver device that receives the multiple location signals and computes the first position and the second position based on the multiple location signals and the first location of the at least one antenna and the second location, different from the first location, of the at least one antenna. 54. The method of claim 34, wherein the processor determining the first bearing to the remote object at the remote object position, different from the first position and different from the second position, based on the first image position includes performing at least one of adding a declination angle and subtracting the declination angle; andwherein the processor determining the second bearing to the remote object at the remote object position based on the second image position includes performing at least one of adding the declination angle and subtracting the declination angle. 55. The method of claim 34, further comprising: an electronic heading device computing a first heading;the electronic heading device computing a second heading;wherein the processor determining the first bearing to the remote object at a remote object position, different from the first position and different from the second position, based on the first image position is further based on the first heading; andwherein the processor determining the second bearing to the remote object at the remote object position based on the second image position is further based on the second heading. 56. The method of claim 55, wherein the first heading includes the second heading. 57. The method of claim 55, wherein the position device includes the electronic heading device. 58. The method of claim 57, wherein the position device includes a global position system (GPS) receiver device that computes the first heading and computes the second heading. 59. The method of claim 55, wherein the electronic heading device includes a digital compass;wherein the digital compass computes the first heading via transforming a magnetic field and a first orientation of the electronic heading device within the magnetic field into a first machine readable signal based on the first heading; andwherein the digital compass computes the second heading via transforming the magnetic field and a second orientation of the electronic bearing device within the magnetic field into a second machine readable signal based on the second heading. 60. The method of claim 55, wherein the electronic heading device includes a plurality of magnetic field sensing devices;wherein the electronic heading device computes the first heading via transforming a magnetic field and a first orientation of the electronic bearing device within the magnetic field into a first machine readable signal via the plurality of magnetic field sensing devices; andwherein the electronic heading device computes the second heading via transforming the magnetic field and a second orientation of the electronic bearing device within the magnetic field into a second machine readable signal via the plurality of magnetic field sensing devices. 61. The method of claim 60, wherein the plurality of magnetic field sensing devices includes a plurality of magnetometers. 62. The method of claim 34, further comprising: the position device providing the first position and the second position to the processor;the at least one camera further providing the first image and the second image to the processor;the processor receiving the first position and the second position from the position device;the processor receiving the first image and the second image from the at least one camera. 63. The method of claim 34, further comprising: the processor receiving multiple data sets;wherein a first data set of the multiple data sets includes the first image and the first position; andwherein a second data set of the multiple data sets includes the second image and the second position. 64. The method of claim 34, wherein the at least one camera includes at least two cameras;wherein the at least one camera acquiring the first image that includes the first remote object image of the remote object and that corresponds to the first position includes a first camera of the at least two cameras acquiring the first image that includes the first remote object image of the remote object and that corresponds to the first position; andwherein the at least one camera acquiring the second image that includes the second remote object image of the remote object and that corresponds to the second position includes a second camera of the at least two cameras acquiring, the second image that includes the second remote object image of the remote object and that corresponds to the second position. 65. The method of claim 64, wherein a first center of view of the first camera is different from a second center of view of the second camera. 66. A non-transitory computer readable memory device that stores instructions, which when executed by a processor, the processor: determines a first position and a second position, different from the first position, via an electronic position device, coupled to at least one antenna, that receives multiple location signals via the at least one antenna and computes the first position and the second position based on the multiple location signals and a first location of the at least one antenna and a second location, different from the first location, of the at least one antenna;acquires, via at least one camera, a first image, as first machine-readable data, that includes a first remote object image of a remote object and that corresponds to the first position;acquires, via the at least one camera, a second image, as second machine-readable data, that includes a second remote object image of the remote object and that corresponds to the second position;determines, via the first machine-readable data, a first image position of the first remote object image of the remote object included by the first image;determines, via the first machine-readable data, a first bearing to the remote object at a remote object position, different from the first position and different from the second position, based on the first image position;determines, via the second machine-readable data, a second image position of the second remote object image of the remote object included by the second image;determines, via the second machine-readable data, a second bearing to the remote object at the remote object position based on the second image position;computes a first rotation, by the first bearing, of a first vector associated with the first position;computes a second rotation, by the second bearing, of a second vector associated with the second position;computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector. 67. The non-transitory computer readable memory device of claim 66, wherein the processor further provides, via a display, information based on the remote object position. 68. The non-transitory computer readable memory device of claim 66, wherein the processor further: receives first user input that indicates the first image position of the first remote object image of the remote object included by the first image; andreceives second user input that indicates the second image position of the second remote object image of the remote object included by the second image. 69. The non-transitory computer readable memory device of claim 68, wherein the processor further displays, via a display, the first image and the second image. 70. The non-transitory computer readable memory device of claim 66, wherein the first image position of the first remote object image of the remote object included by the first image is based on a first number of pixels;wherein the second image position of the second remote object image of the remote object included by the second image is based on a second number pixels;wherein when the processor determines the first bearing to the remote object at the remote object position, the processor utilizes the first number of pixels; andwherein when the processor determines the second bearing to the remote object at the remote object position via the second image position, the processor utilizes the second number of pixels. 71. The non-transitory computer readable memory device of claim 70, wherein when the processor determines the first bearing to the remote object at the remote object position, utilizing the first number of pixels, the processor utilizes at least one of a first function of number of pixels to angles and a first mapping of number of pixels to angles; andwherein when the processor determines the second bearing to the remote object at the remote object position via the second image position, utilizing the second number of pixels, the processor utilizes at least one of a second function of number of pixels to angles and a second mapping of number of pixels to angles. 72. The non-transitory computer readable memory device of claim 71, wherein the at least one of the second function of number of pixels to angles and the second mapping of number of pixels to angles is the at least one of the first function of number of pixels to angles and the first number of mapping of pixels to angles. 73. The non-transitory computer readable memory device of claim 70, wherein the second number of pixels equals the first number of pixels. 74. The non-transitory computer readable memory device of claim 66, wherein the processor further acquires, via the at least one camera, at least one of a motion picture and a video that includes the first image and the second image. 75. The non-transitory computer readable memory device of claim 66, wherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes an intersection of a first plane and a second plane, different from the first plane;wherein the first plane includes the first position and the remote object position;wherein the second plane includes the second position and the remote object position; andwherein the intersection of the first plane and the second plane indicates the remote object position. 76. The non-transitory computer readable memory device of claim 66, wherein the processor further: computes, utilizing the first position, a first plane, wherein the first plane is normal to the first vector and the first plane initially includes the first position, a geographic pole, and an origin; andcomputes, utilizing the second position, a second plane, wherein the second plane is normal to the second vector and the second plane initially includes the second position, the geographic pole, and the origin;wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor computes a rotation of the first plane about the first position by the first bearing such that the first plane no longer includes the geographic pole and includes the first position, the origin, and the remote object position;wherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor computes a rotation of the second plane about the second position by the second bearing such that the second plane no longer includes the geographic pole and includes the second position, the origin, and the remote object position; andwherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes an intersection of the first plane and the second plane. 77. The non-transitory computer readable memory device of claim 66, wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor: computes a first quaternion, utilizing the first position and the first bearing;computes a second quaternion, utilizing the first vector;computes an inverse of the first quaternion as a third quaternion; andcomputes a first quaternion multiplication of the first quaternion, the second quaternion, and the third quaternion; andwherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor: computes a fourth quaternion, utilizing the second position and the second bearing;computes a fifth quaternion, utilizing the second vector;computes an inverse of the fourth quaternion as a sixth quaternion; andcomputes a second quaternion multiplication of the fourth quaternion, the fifth quaternion, and the sixth quaternion. 78. The non-transitory computer readable memory device of claim 66, wherein the first rotation, by the first bearing, of the first vector is associated with a third vector;wherein the second rotation, by the second bearing, of the second vector is associated with a fourth vector; andwherein when the processor computes the remote object position based on the first rotation, by the first bearing, of the first vector and the second rotation, by the second bearing, of the second vector, the processor computes a cross product of the third vector and the fourth vector, wherein the cross product indicates the remote object position. 79. The non-transitory computer readable memory device of claim 78, wherein the processor further: computes, utilizing the first position, the first vector normal to the first position, an origin, and a geographic pole; andcomputes, utilizing the second position, the second vector normal to the second position, the origin, and the geographic pole;wherein when the processor computes the first rotation, by the first bearing, of the first vector associated with the first position, the processor computes a first transform of the first vector into the third vector, wherein the processor computes the first rotation of the first vector about the first position by the first bearing; andwherein when the processor computes the second rotation, by the second bearing, of the second vector associated with the second position, the processor computes a second transform of the second vector into the fourth vector, wherein the processor computes the second rotation of the second vector about the second position by the second bearing. 80. The non-transitory computer readable memory device of claim 66, wherein the processor further: determines a first heading via an electronic heading device; anddetermines a second heading via the electronic heading device;wherein when the processor determines the first bearing to the remote object at the remote object position based on the first image position, the processor determines the first bearing to the remote object at the remote object position further based on the first heading; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor determines the second bearing to the remote object at the remote object position further based on the second heading. 81. The non-transitory computer readable memory device of claim 80, wherein the first heading includes the second heading. 82. The non-transitory computer readable memory device of claim 80, wherein the position device includes the electronic heading device. 83. The non-transitory computer readable memory device of claim 82, wherein a first center of view of the first camera is different from a second center of view of the second camera. 84. The non-transitory computer readable memory device of claim 82, wherein the position device includes a global position system (GPS) receiver device that computes the first heading and computes the second heading. 85. The non-transitory computer readable memory device of claim 66, wherein the processor further: determines a first heading via an electronic heading device; anddetermines a second heading via the electronic heading device;wherein the electronic heading device computes the first heading via a first transform of a magnetic field and a first orientation of the electronic bearing device within the magnetic field into a first machine readable signal based on the first heading;wherein the electronic heading device computes the second heading via a second transform of the magnetic field and a second orientation of the electronic bearing device within the magnetic field into a second machine readable signal based on the second heading;wherein when the processor determines the first bearing to the remote object at the remote object position based on the first image position, the processor determines the first bearing to the remote object at the remote object position further based on the first heading via the first machine readable signal; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor determines the second bearing to the remote object at the remote object position further based on the second heading via the second machine readable signal. 86. The non-transitory computer readable memory device of claim 85, wherein the electronic heading device includes a plurality of magnetic field sensor devices;wherein the electronic heading device computes the first heading via the first transform of the magnetic field and the first orientation of the electronic heading device within the magnetic field into the first machine readable signal via the plurality of magnetic field sensor devices; andwherein the electronic heading device computes the second heading via the second transform of the magnetic field and the second orientation of the electronic heading device within the magnetic field into the second machine readable signal via the plurality of magnetic field sensor devices. 87. The non-transitory computer readable memory device of claim 86, wherein the plurality of magnetic field sensor devices includes a plurality of magnetometers. 88. The non-transitory computer readable memory device of claim 66, wherein when the processor determines the first position and the second position, different from the first position, via the electronic position device, coupled to the at least one antenna, that receives the multiple location signals via the at least one antenna and computes the first position and the second position based on the multiple location signals and the first location of the at least one antenna and the second location, different from the first location, of the at least one antenna, the processor: determines the first position while the at least one antenna is moving at a first speed; anddetermines the second position while the at least one antenna is moving at a second speed. 89. The non-transitory computer readable memory device of claim 88, wherein the second speed is the first speed. 90. The non-transitory computer readable memory device of claim 66, wherein the processor further receives multiple data sets;wherein a first data set of the multiple data sets includes the first image and the first position; andwherein a second data set of the multiple data sets includes the second image and the second position. 91. The non-transitory computer readable memory device of claim 66, wherein the position device includes a global position system (GPS) receiver device. 92. The non-transitory computer readable memory device of claim 66, wherein when the processor determines the first bearing to the remote object at the remote object position, different from the first position and different from the second position, based on the first image position, the processor performs at least one of adding a declination angle and subtracting the declination angle; andwherein when the processor determines the second bearing to the remote object at the remote object position based on the second image position, the processor performs at least one of adding the declination angle and subtracting the declination angle. 93. The non-transitory computer readable memory device of claim 66, wherein the at least one camera includes at least two cameras;wherein when the processor acquires, via the at least one camera, the first image that includes the first remote object image of the remote object and that corresponds to the first position, the processor acquires, via a first camera of the at least two cameras, the first image that includes the first remote object image of the remote object and that corresponds to the first position; andwherein when the processor acquires, via the at least one camera, the second image that includes the second remote object image of the remote object and that corresponds to the second position, the processor acquires, via a second camera of the at least two cameras, the second image that includes the second remote object image of the remote object and that corresponds to the second position. 94. The non-transitory computer readable memory device of claim 66, wherein the at least one camera acquires the first image that includes the first remote object image and that corresponds to the first position, the at least one camera moves at a first speed; andwherein the at least one camera acquires the second image that includes the second remote object image and that corresponds to the second position, the at least one camera moves at a second speed. 95. The non-transitory computer readable memory device of claim 94, wherein the second speed is the first speed.