The inventions described below relate the field of astronomy, specifically to an electronic device capable of locating and identifying celestial objects.
Norton, Viewing And Display Apparatus, U.S. Pat. No. 5,311,203 (May 10, 1994) describes a viewing device for identifying features of interest which appear in the field of view of the device. Though Norton was described in the context of a hand-held star-gazing device, and purported to provide information about asterisms (constellations or groups of stars) in the field of view, the device does not work unless held with certain components held perfectly vertical during use. Any twisting or rotation of the device about the viewing axis necessarily causes errors, and introduces ambiguity that cannot be resolved. Thus, it is not possible to implement the Norton system, as proposed by Norton, in a hand-held device. Norton consists of a box-like housing with a viewing channel therethrough, an LCD display and image overlay system for superimposing an image on the field of view, optics for manipulating the superimposed image to make it appear at infinity, a single axis eccentrically weighted inclinometer to measure inclination of the device and three magnetic sensors to determine the bearing of the device, a database with information regarding the constellations which might be viewed with the device, and a microprocessor. The viewing channel establishes a field of view for the user, through which the user can see constellations. The microprocessor is programmed to interpret sensor input and search the database for constellations in the field of view, and transmit a reference display data to the display.
The Norton system suffers from crippling defects. An operational device depends on perfect vertical alignment of the inclinometer. Without perfect vertical alignment of the inclinometer the device cannot unambiguously determine its orientation. The slightest deviation from vertical introduces ambiguity, such that the device can determine only that the viewing channel is aligned somewhere on a wide arc of the sky. If the device is not held perfectly vertically, that is, if it is twisted or rotated about the viewing axis, projection errors are introduced into the output from the inclinometer, so that the device has inadequate information regarding its inclination. In the case that the twist induced error is small enough that the device can determine its viewing axis with enough precision to generate a reference display that corresponds to constellations in the field of view, the device has no way to determine that it is twisted, and thus cannot rotate the reference display to align with the constellation.
Our own patents, Lemp, Celestial Object Location Device, U.S. Pat. No. 6,366,212 (Apr. 2, 2002) and U.S. Pat. No. 6,570,506 (May 27, 2003) and our pending patent application Lemp, U.S. Publication 20030218546 (Nov. 27, 2003) (the entirety of which is hereby incorporated by reference) provides solutions to this problem. Lemp shows a device for viewing celestial objects from a location at a time and date ascertained by the device, comprising a viewing means to observe along a viewing axis defined by an azimuth angle and a nadir angle or altitude; a processor, a multi-axis magnetic sensor adapted to provide the processor with azimuth data representing the azimuth angle, a multi-axis gravitational sensor adapted to provide the processor with nadir data representing the nadir angle; location means for providing location data representing the location of the viewing device to the processor; time means for providing time and date data representing the time and date to the processor; and a database adapted to be accessed by the processor and provide data such that the processor determines celestial coordinates of right ascension and declination corresponding to the viewing axis based on the azimuth data, the nadir data, the location data, and the time and date data. The device can be used to direct a user to a celestial object (its resolution is very high, so that it can direct the user to individual stars and planets, as well as constellations and asterisms) and it can be used to identify an object to which the user has pointed the device.
The position sensing function of the device is most accurately determined using a three axis magnetic sensor and a three axis gravitational sensor. The use of lesser arrays will generally result in reduced accuracy and resolution of the device, such that it will be desirable to improve the resolution with the methods described below, especially when the devices are embodied in celestial object location devices with magnifying optics.
The devices and methods described below provide for enhanced accuracy of position sensing in a celestial object location device using sensor arrays of less than three axes. Information that would otherwise be provided by a third axis gravitational sensor, for example, is obtained by estimation based on input from the two gravitational sensors provided, or determined with limitations from the two gravitational sensors provided.
These arrays of sensors may be used to determine the direction in which the celestial object location is pointed, and the degree to which it is twisted about the viewing axis, within the typical viewing situations. The use of arrays with gravitational sensor arrays and/or magnetic field arrays with sensors oriented on less than three axes will generally result in reduced accuracy and resolution of the device, such that improved accuracy may be desired when the device is embodied in celestial object location devices with magnifying optics, and the devices and methods described herein provide for enhanced accuracy of position sensing in a celestial object location device using sensor arrays of less than three axes. The new methods of calculating position of a celestial object location device which incorporates only two gravitational sensors may be employed if one sensor involves estimating the missing third axis sensor via the magnitude of the existing two, and an estimate or calculation of the magnitude of the local gravity vector, from there it is similar to a full 3+3 system. The degree of error encountered in the necessary calculations can be greatly reduced with the algorithms described in the following paragraphs.
In the first method presented here, the missing component of the gravity information is calculated using the input from the existing sensors. As initial steps, the system is initialized, a process which includes system startup and obtains position data and time data from appropriate sources (preferably GPS and its associated time signal and/or an onboard clock, though time and location can be manually input, or obtained from satellite broadcast time signals and alternative satellite or navigational locating systems). The system then determines error correction factors for sensor characteristics, such as alignment errors, temperature corrections, and other errors and biases. Some of these steps are performed at system startup and periodically during use.
Thereafter, the system receives and interprets input from the magnetic field sensor array and the gravitational sensor array. The algorithm first determines the nadir angle of the device by using the gravitational sensor array to calculate the gravity vector and its relationship to the viewing axis. To accomplish this, the system receives input from the gravitational sensors, and then estimates the input from the “missing” gravitational sensor via an equation such as the following:
z=√{square root over (grav2−(x2+y2))}
where z is the missing component, grav=estimated or calculated gravity field magnitude for the current location (though the calculation can assume gravity equals one g in most cases, or resort to a more precise gravitational model where additional accuracy is desired), x is the value corresponding to the signal from the gravitational sensor which is parallel to sighting channel (item 22x), and y is the value corresponding to the signal from the gravitational sensor which is perpendicular to sighting channel (item 22y). With this information, the system determines the gravity vector, which is comprised of the direction and magnitude of the sensed gravity.
Next, the system calculates a projection of the gravity vector onto the device-coordinate y-z plane. This step is illustrated in
Next, the system determines the “twist” of the device, which is the rotation angle of the gravity vector (or its projection) about the viewing axis, using the y-axis as a starting point. To determine the rotation angle, the microprocessor calculates the angle between the gravitational vector projection and the device y-axis (which is established by gravitational sensor 22y).
Next, the system virtually “de-rotates” the device by rotating the gravity vector projection about the device x-axis by the rotation angle. This provides the basis for determining the nadir angle of the device, as that is the rotation of the device about its y-axis (which has been rotated to match the local horizontal plane). This step is illustrated in
Next, the system calculates the nadir angle of the rotated gravity vector projection, using the x-axis sensor.
With the nadir angle calculated, the system proceeds to use the input of the magnetic field sensors to determine the azimuth angle. This is done by taking the magnetic field sensor input to calculate a magnetic field vector, and then transforming the magnetic field vector into horizon coordinates (terrestrial coordinates defined relative to the earth's local horizontal plane). This is accomplished by virtually rotating the magnetic field vector about the device x-axis by the rotation angle. This is illustrated in
With the azimuth angle and the nadir angle determined, the device knows where it is pointed in the sky, and can determine, as required by the user input, what celestial objects appear in its field of view (for the identify function) or where the user must be prompted, by appropriate output, to move the device to align the viewing axis with a desired celestial object (for the locate function).
In the second method of position sensing, rather than estimate a third axis gravitational input, the system uses the gravitational sensor parallel to the viewing axis (22x) to calculate the altitude, and uses the gravitational sensor perpendicular to the sighting channel to calculate device rotation. Once these two angles are read, calculations proceed in a manner similar to a full 3-axis gravitational/3-axis magnetic field sensor system. Again, as initial steps, the system is initialized, including system startup and obtaining position data and time data from appropriate sources, and the system determines error correction factors for sensor characteristics, such as alignment errors, temperature corrections, and other errors and biases.
Next, the system determines nadir angle on the basis of the input of the x-axis gravitational sensor 22x, using an estimated or known local gravity magnitude (estimated gravity magnitude should be sufficient for handheld devices with little or no magnification). The rotation angle of the device is then determined based on the output of y-axis gravitational sensor 22y, which is perpendicular to the viewing axis. The step of estimating the third axis gravitational vector is not used in this method.
Next, the system determines the azimuth angle as above. This includes determining the overall magnetic field vector M by combining the input from the three magnetic field sensors 21x, 21y and 21z, transforming the magnetic field vector so that it is in terrestrial coordinates with an x-y plane parallel to the local ground plane, and completing this transform to terrestrial coordinates by rotating this vector about the device y-axis by the rotation angle, and projecting this resulting vector onto the terrestrial x-y plane, and then determining the azimuth angle of the device by calculating the angel between the projected vector and the device x-axis. Again, the system may optionally compare the measured magnetic vector with the known local dip angle and the expected magnitude of the magnetic field for correlation with a magnetic model, and the system will preferably add a correction to the calculated azimuth angle for the known magnetic declination correction (suitable corrections techniques are disclosed in our co-pending U.S. App. 10/444,788).
For both methods, the system may make use of the known dip angle (which is determined by the known terrestrial position and the magnetic model stored in the database), and the measured magnetic field vector to determine provide additional input to the nadir angle calculation. In this method, the system determines the nadir angle based on the gravitational sensors and the local vertical as established by the comparison of the magnetic vector and the dip angle.
The method described above can be implemented with a variety of gravitational sensors and magnetic field sensors. They can even be implemented with inclinometers instead of gravitational sensors, though the range in which the device can provide accurate location and identify functionality may be limited. Also, the steps indicated above may be accomplished in any appropriate order. Though the calculations have been described in relation to linear algebra techniques suitable for the underlying calculations, the calculations may be performed using spherical trigonometry techniques (such techniques being equivalent to the underlying linear algebra). The methods and devices may be incorporated into Celestial Object Location devices comprising scopes with out optics or magnification, telescopes and binoculars, or any other viewing means. Thus, while the preferred embodiments of the devices and methods have been described in reference to the environment in which they were developed, they are merely illustrative of the principles of the inventions. Other embodiments and configurations may be devised without departing from the spirit of the inventions and the scope of the appended claims.
This application is a continuation of U.S. App. 10/861,032 filed Jun. 4, 2004, now U.S. Pat. No. 7,010,862.
Number | Date | Country | |
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Parent | 10861032 | Jun 2004 | US |
Child | 11376670 | Mar 2006 | US |