Patent Publication Number: US-2022229178-A1

Title: Beamforming sonar system with improved sonar image functionality, and associated methods

Description:
CROSS-REFERENCE TO RELATED APPLICATION(S) 
     This application is a continuation of U.S. patent application Ser. No. 16/944,186, filed Jul. 31, 2020, entitled “Beamforming Sonar System with Improved Sonar Image Functionality, and Associated Methods”; which is hereby incorporated by reference in its entirety. 
    
    
     FIELD OF THE INVENTION 
     Embodiments of the present invention relate generally to sonar systems, and more particularly, to beamforming sonar systems. 
     BACKGROUND OF THE INVENTION 
     Sonar (SOund Navigation And Ranging) has been used to detect waterborne or underwater objects. For example, sonar devices may be used to determine depth and bottom topography, detect fish, locate wreckage, etc. In this regard, due to the extreme limits to visibility underwater, sonar is typically the most accurate way to locate objects underwater and provide an understanding of the underwater environment. Sonar transducer elements convert electrical energy into sound or vibrations. Sonar signals are transmitted into and through the water and reflected from encountered objects (e.g., fish, bottom surface, underwater structure, etc.). The transducer elements receive the reflected sound as sonar returns and convert the sound energy into electrical energy (e.g., sonar return data). Based on the known speed of sound, it is possible to determine the distance to and/or location of the waterborne or underwater objects. The sonar return data can also be processed to be displayed on a display device, giving the user a “picture” (or image) of the underwater environment. 
     Different types of sonar systems provide different sonar functionality, many with differing benefits. As such, there is need for sonar systems with improved sonar image functionality while still providing a reasonable cost to the user (e.g., an angler). 
     BRIEF SUMMARY OF THE INVENTION 
     Example embodiments of the present invention provide various sonar systems for imaging an underwater environment. Some example sonar systems include one or more arrays of transducer elements and a corresponding sonar signal processor(s). The array(s) are operated to transmit sonar signals into the underwater environment. The array(s) are also operated at a fixed phase shift, but vary in frequency so as to beamform multiple sonar return beams. The multiple sonar return beams can be filtered through based on frequency between a first range of angles and between a second range of angles. A gap is formed between the first range of angles and the second range of angles. This gap can be covered up by utilizing additional arrays that are oriented differently such that a first range of angles and/or a second range of angles of that array cover (at least a portion of) the underwater volume within the gap. By using three arrays, so oriented, continuous sonar coverage extending for ˜135° can be achieved. Further, with the ability to beamform multiple sonar return beams of around 0.5°-1° each all along that 135° (by varying frequency)—precise sonar return data specific to a small slice of the underwater environment can be used to form two-dimensional (2D) near-real time (or “live”) sonar images. 
     Further, some example embodiments, provide a sonar system configured to utilize certain ones or more of the beamformed sonar return beams to form other types of sonar images. For example, anglers have gotten used to seeing downward facing sonar images that build-up over time to show a running view of the underwater environment below the watercraft. Instead of requiring additional transducer elements specifically designed to create such images, some embodiments contemplate utilizing certain ones or more of the beamformed sonar return beams. This saves space in the sonar system and provides increased functionality while saving the user from having to buy multiple sonar systems. 
     As an example, in some embodiments, a high resolution downward sonar image is formed by selecting the beamformed sonar return beam that is substantially straight down from the watercraft. With a beamwidth of ˜1° (in the fore-to-aft direction) by ˜20° (in the port-to-starboard direction), the resulting downward sonar image provides high resolution sonar imagery. 
     Additionally, multiple ones of the beamformed sonar return beams can be used to form a downward sonar image that produces desirable “fish arches” that anglers are used to seeing on the sonar image (indicating the presence of fish). For example, a number of beamformed sonar return beams (together facing generally downward) could be selected that together form a beamwidth of ˜20° (in the fore-to-aft direction) by ˜20° (in the port-to-starboard direction), with the resulting downward sonar image providing sonar imagery with the desirable fish arches. In some cases, the selected sonar return beams may span between two or more different arrays (such as depending on the orientation of the arrays and the desired volume of the underwater environment). 
     In some embodiments, the sonar system may be configured to present the fish arches gathered from the multiple sonar return beams into a sonar image also formed from the single sonar return beam, with the fish arches being presented at the appropriate position (e.g., depth and time). This forms a combined downward sonar image with high resolution, but also including the desirable fish arches. This may all be achieved using the one sonar system, and without dedicated linear or conical transducer elements. 
     In some embodiments, the specific mounting orientation and position of the arrays with respect to each other may provide a small footprint while still providing the desired functionality—which can reduce costs and reduce potential negative effects, such as drag or risk of hitting underwater objects (such as may be caused by a larger transducer assembly within the water). 
     In some embodiments, the above multiple types of sonar images may still be achieved with a single array of transducer elements (e.g., as opposed to two or three (or more) arrays). This provides improved sonar functionality at even less of a cost to the user. 
     In an example embodiment, a system for imaging an underwater environment of a body of water is provided. The system comprises at least one array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction, wherein the facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The system further includes a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a sonar image of the underwater environment downward from the watercraft by: determining one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined one of the multiple sonar return beams forms a fan-shaped beam that is relatively narrow in the fore-to-aft direction and relatively wide in a port-to-starboard direction; determining a plurality of the multiple sonar return beams that corresponds to a fourth range of angles in the fore-to-aft direction including at least the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined plurality of the multiple sonar return beams form a beam shape that is relatively wide in both the fore-to-aft direction and the port-to-starboard direction; and forming the sonar image from both the one of the multiple sonar return beams and the plurality of the multiple sonar return beams. The sonar image is formed from: a plurality of first sonar image portions that corresponds to sonar return data from the one of the multiple sonar return beams received at different times, wherein the plurality of first sonar image portions are built up over time; and a plurality of second sonar image portions that each correspond to a fish arch generated from the plurality of multiple sonar return beams, wherein the plurality of second sonar image portions are positioned within the plurality of first sonar image portions so as to correspond to a depth and a time associated with sonar return data taken from the plurality of multiple sonar return beams. 
     In some embodiments, the sonar signal processor is configured to: determine the fish arch from within sonar return data corresponding to the plurality of multiple sonar return beams that have been received across at least two or more time receipts; and generate at least one second sonar image portion based on the sonar return data corresponding to the determined fish arch. In some embodiments, the sonar signal processor is further configured to only determine the fish arch in an instance when the fish arch includes a size above a size threshold. In some embodiments, the sonar signal processor is configured to generate the at least one second sonar image portion by removing or nullifying sonar image data within the sonar return data that is not the determined fish arch. 
     In some embodiments, the sonar signal processor is configured to form the sonar image by: determining the depth and time associated with the sonar return data corresponding to the fish arch; and positioning the generated at least one second sonar image portion at the position within the plurality of first sonar image portions at the determined depth and time. 
     In some embodiments, the sonar signal processor is configured to form the sonar image by causing the plurality of second sonar image portions to overlay the plurality of first sonar image portions. 
     In some embodiments, the sonar signal processor is configured to form the sonar image by causing the plurality of second sonar image portions to replace corresponding portions of the plurality of first sonar image portions. 
     In some embodiments, the fourth range of angles includes angles that extend to each side of the angle within the first range of angles that is substantially straight downward from the watercraft. In some embodiments, the fourth range of angles are selected such that the angle within the first range of angles that is substantially straight downward from the watercraft is generally in the center of the fourth range of angles. 
     In some embodiments, the fourth range of angles comprises a total range of angles of at least 10°. 
     In some embodiments, the system further comprises an orientation sensor configured to determine an orientation of the array with respect to a top surface of the body of water, and the sonar signal processor is configured to determine the one of the multiple sonar return beams that corresponds to the angle within the first range of angles that is substantially straight downward from the watercraft based on data from the orientation sensor. In some embodiments, the sonar signal processor is configured to determine the plurality of the multiple sonar return beams that corresponds to the fourth range of angles in the fore-to-aft direction based on data from the orientation sensor. 
     In some embodiments, the sonar signal processor is further configured to generate a second sonar image of the underwater environment forward and downward from the watercraft, wherein the second sonar image is a two-dimensional live sonar image that is formed of sonar return data from each of the multiple sonar return beams, and wherein the sonar return data used to form the two-dimensional live sonar image was received at substantially a same time by the plurality of transducer elements. 
     In some embodiments, the array is a first array and the emitting face of the first array is a first emitting face and the facing direction is a first facing direction, and the system further comprises a second array of a plurality of second transducer elements mounted to the watercraft and oriented with a second emitting face in a second facing direction that is different than the first facing direction. The second facing direction is generally forward and downward of the watercraft. Each of the plurality of second transducer elements are configured to operate at the fixed phase shift and vary in frequency so as to beamform multiple second sonar return beams between a fifth range of angles in the fore-to-aft direction and a sixth range of angles in the fore-to-aft direction. The fifth range of angles is symmetrical to the sixth range of angles with respect to the second facing direction. A gap of a seventh range of angles in the fore-to-aft direction separates the fifth range of angles and the sixth range of angles. The second emitting face of the second array is oriented with respect to the first emitting face of the first array such that at least one of the fifth range of angles or the sixth range of angles extends within the gap of the third range of angles from the first array. In some embodiments, the sonar signal processor is configured to determine the plurality of the multiple sonar return beams that corresponds to the fourth range of angles in the fore-to-aft direction so as to include at least one of the multiple sonar return beams from the first range of angles corresponding to sonar return data received from the first array and at least one of the multiple second sonar return beams from the fifth range of angles corresponding to sonar return data received from the second array. In some embodiments, the system further comprises a third array of a plurality of third transducer elements mounted to the watercraft and oriented with a third emitting face in a third facing direction that is different than both the first facing direction and the second facing direction, wherein the first array and the third array are mounted in an X configuration and the second array is mounted in an offset position from a center of the X configuration. 
     In another example embodiment, a system for imaging an underwater environment of a body of water is provided. The system comprises a single array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction, wherein the facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The system further includes a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a sonar image of the underwater environment downward from the watercraft by: determining one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined one of the multiple sonar return beams forms a fan-shaped beam that is relatively narrow in the fore-to-aft direction and relatively wide in a port-to-starboard direction; determining a plurality of the multiple sonar return beams that corresponds to a fourth range of angles in the fore-to-aft direction including at least the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined plurality of the multiple sonar return beams form a beam shape that is relatively wide in both the fore-to-aft direction and the port-to-starboard direction; and forming the sonar image from both the one of the multiple sonar return beams and the plurality of the multiple sonar return beams. The sonar image is formed from: a plurality of first sonar image portions that corresponds to sonar return data from the one of the multiple sonar return beams received at different times, wherein the plurality of first sonar image portions are built up over time; and a plurality of second sonar image portions that each correspond to a fish arch generated from the plurality of multiple sonar return beams, wherein the plurality of second sonar image portions are positioned within the plurality of first sonar image portions so as to correspond to a depth and a time associated with sonar return data taken from the plurality of multiple sonar return beams. 
     In yet another example embodiment, a transducer assembly for imaging an underwater environment of a body of water is provided. The transducer assembly comprises at least one array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction, wherein the facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The transducer assembly further comprises a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a sonar image of the underwater environment downward from the watercraft by: determining one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined one of the multiple sonar return beams forms a fan-shaped beam that is relatively narrow in the fore-to-aft direction and relatively wide in a port-to-starboard direction; determining a plurality of the multiple sonar return beams that corresponds to a fourth range of angles in the fore-to-aft direction including at least the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the determined plurality of the multiple sonar return beams form a beam shape that is relatively wide in both the fore-to-aft direction and the port-to-starboard direction; and forming the sonar image from both the one of the multiple sonar return beams and the plurality of the multiple sonar return beams. The sonar image is formed from: a plurality of first sonar image portions that corresponds to sonar return data from the one of the multiple sonar return beams received at different times, wherein the plurality of first sonar image portions are built up over time; and a plurality of second sonar image portions that each correspond to a fish arch generated from the plurality of multiple sonar return beams, wherein the plurality of second sonar image portions are positioned within the plurality of first sonar image portions so as to correspond to a depth and a time associated with sonar return data taken from the plurality of multiple sonar return beams. 
     In yet another example embodiment, a system for imaging an underwater environment of a body of water is provided. The system comprises at least one array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction. The facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The system further includes a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a first sonar image of the underwater environment forward and downward from the watercraft, wherein the first sonar image is a two-dimensional live sonar image that is formed of sonar return data from each of the multiple sonar return beams, and wherein the sonar return data used to form the two-dimensional live sonar image was received at substantially a same time by the plurality of transducer elements. The sonar signal processor is further configured to generate a second sonar image of the underwater environment downward from the watercraft, wherein the second sonar image is formed from at least one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the second sonar image is formed of a plurality of sonar image portions built up over time, and wherein each of the plurality of sonar image portions corresponds to sonar return data from the at least one of the multiple sonar return beams received at different times. 
     In some embodiments, the sonar signal processor is configured to generate the second sonar image by forming the second sonar image from one of the multiple sonar return beams that corresponds to the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the one of the multiple sonar return beams form a fan-shaped beam that is relatively narrow in the fore-to-aft direction and relatively wide in a port-to-starboard direction. In some embodiments, the system further comprises an orientation sensor configured to determine an orientation of the array with respect to a top surface of the body of water, and wherein the sonar signal processor is configured to determine the one of the multiple sonar return beams that corresponds to the angle within the first range of angles that is substantially straight downward from the watercraft based on data from the orientation sensor. 
     In some embodiments, the sonar signal processor is configured to generate the second sonar image by forming the second sonar image from a plurality of the multiple sonar return beams that corresponds to a fourth range of angles in the fore-to-aft direction including at least the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the plurality of the multiple sonar return beams form a beam shape that is relatively wide in both the fore-to-aft direction and a port-to-starboard direction. In some embodiments, the system further comprises an orientation sensor configured to determine an orientation of the array with respect to a top surface of the body of water, and wherein the sonar signal processor is configured to determine the plurality of the multiple sonar return beams that corresponds to the fourth range of angles in the fore-to-aft direction based on data from the orientation sensor. In some embodiments, the fourth range of angles includes angles that extend to each side of the angle within the first range of angles that is substantially straight downward from the watercraft. In some embodiments, the fourth range of angles are selected such that the angle within the first range of angles that is substantially straight downward from the watercraft is generally in the center of the fourth range of angles. In some embodiments, the fourth range of angles comprises a total range of angles of at least 10°. In some embodiments, the sonar signal processor is further configured to generate a third sonar image of the underwater environment downward from the watercraft, wherein the third sonar image is formed from one of the multiple sonar return beams that corresponds to the angle within the first range of angles that is substantially straight downward from the watercraft, wherein the third sonar image is formed of a plurality of second sonar image portions built up over time, and wherein each of the plurality of second sonar image portions corresponds to sonar return data from the one of the multiple sonar return beams received at different times. 
     In some embodiments, the array is a first array and the emitting face of the first array is a first emitting face and the facing direction is a first facing direction, and the system further comprises a second array of a plurality of second transducer elements mounted to the watercraft and oriented with a second emitting face in a second facing direction that is different than the first facing direction, wherein the second facing direction is generally forward and downward of the watercraft. Each of the plurality of second transducer elements are configured to operate at the fixed phase shift and vary in frequency so as to beamform multiple second sonar return beams between a fifth range of angles in the fore-to-aft direction and a sixth range of angles in the fore-to-aft direction. The fifth range of angles is symmetrical to the sixth range of angles with respect to the second facing direction. A gap of a seventh range of angles in the fore-to-aft direction separates the fifth range of angles and the sixth range of angles. The second emitting face of the second array is oriented with respect to the first emitting face of the first array such that at least one of the fifth range of angles or the sixth range of angles extends within the gap of the third range of angles from the first array. In some embodiments, the sonar signal processor is configured to generate the second sonar image by forming the second sonar image from a plurality of the multiple sonar return beams that corresponds to a fourth range of angles in the fore-to-aft direction including at least the angle within the first range of angles that is substantially straight downward from the watercraft, and the sonar signal processor is configured to determine the plurality of the multiple sonar return beams that corresponds to the fourth range of angles in the fore-to-aft direction so as to include at least one of the multiple sonar return beams from the first range of angles corresponding to sonar return data received from the first array and at least one of the multiple second sonar return beams from the fifth range of angles corresponding to sonar return data received from the second array. In some embodiments, the system further comprises a third array of a plurality of third transducer elements mounted to the watercraft and oriented with a third emitting face in a third facing direction that is different than both the first facing direction and the second facing direction, and the first array and the third array are mounted in an X configuration and the second array is mounted in an offset position from a center of the X configuration. 
     In some embodiments, the system further comprises a user interface including a display, wherein the user interface is configured to receive user input, and wherein the sonar signal processor is configured to receive an indication of user input indicating a desire to present the second sonar image and, in response, cause the user interface to present the second sonar image. In some embodiments, the sonar signal processor is configured to receive an indication of user input indicating a desire to present both the first sonar image and the second sonar image and, in response, cause the user interface to present both the first sonar image and the second sonar image in split screen mode. 
     In yet another example embodiment, a system for imaging an underwater environment of a body of water is provided. The system comprises a single array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction, wherein the facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The system further includes a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a first sonar image of the underwater environment forward and downward from the watercraft, wherein the first sonar image is a two-dimensional live sonar image that is formed of sonar return data from each of the multiple sonar return beams, and wherein the sonar return data used to form the two-dimensional live sonar image was received at substantially a same time by the plurality of transducer elements. The sonar signal processor is further configured to generate a second sonar image of the underwater environment downward from the watercraft, wherein the second sonar image is formed from at least one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the second sonar image is formed of a plurality of sonar image portions built up over time, wherein each of the plurality of sonar image portions corresponds to sonar return data from the at least one of the multiple sonar return beams received at different times. 
     In yet another example embodiment, a transducer assembly for imaging an underwater environment of a body of water is provided. The transducer assembly comprises at least one array of a plurality of transducer elements mounted to a watercraft on the body of water and oriented with an emitting face in a facing direction, wherein the facing direction is generally forward and downward of the watercraft. The emitting face defines a width and a length, the length of the emitting face is greater than the width of the emitting face, and the length of the emitting face extends in a fore-to-aft direction of the watercraft. Each of the plurality of transducer elements defines a length and a width, wherein the length of each of the plurality of transducer elements is greater than the width of each of the plurality of transducer elements, and wherein the length of each of the plurality of transducer elements is perpendicular to the length of the emitting face. The plurality of transducer elements are configured to transmit one or more sonar beams into the underwater environment. Each of the plurality of transducer elements are configured to operate at a fixed phase shift and vary in frequency so as to beamform multiple sonar return beams between a first range of angles in the fore-to-aft direction and a second range of angles in the fore-to-aft direction. The first range of angles is symmetrical to the second range of angles with respect to the facing direction. A gap of a third range of angles in the fore-to-aft direction separates the first range of angles and the second range of angles. The transducer assembly further includes a sonar signal processor in communication with the array and configured to: operate the array to cause the plurality of transducer elements to transmit the one or more sonar beams into the underwater environment; receive sonar return data from the plurality of transducer elements of the array; and filter the sonar return data based on frequency to form the multiple sonar return beams. The sonar signal processor is further configured to generate a first sonar image of the underwater environment forward and downward from the watercraft, wherein the first sonar image is a two-dimensional live sonar image that is formed of sonar return data from each of the multiple sonar return beams, and wherein the sonar return data used to form the two-dimensional live sonar image was received at substantially a same time by the plurality of transducer elements. The sonar signal processor is further configured to generate a second sonar image of the underwater environment downward from the watercraft, wherein the second sonar image is formed from at least one of the multiple sonar return beams that corresponds to an angle within the first range of angles that is substantially straight downward from the watercraft, wherein the second sonar image is formed of a plurality of sonar image portions built up over time, wherein each of the plurality of sonar image portions corresponds to sonar return data from the at least one of the multiple sonar return beams received at different times. 
     Associated methods of operating and manufacturing various example systems and transducer assemblies described herein are also contemplated. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Having thus described the invention in general terms, reference will now be made to the accompanying drawings, which are not necessarily drawn to scale, and wherein: 
         FIG. 1  illustrates an example watercraft including various sonar transducer assemblies, in accordance with some embodiments discussed herein; 
         FIG. 2A  illustrates an example array of transducer elements, in accordance with some embodiments discussed herein; 
         FIG. 2B  illustrates a side view of the array of transducer elements shown in  FIG. 2A , wherein an example first range of angles and an example second range of angles for beamformed sonar return beams are illustrated, in accordance with some embodiments discussed herein; 
         FIG. 2C  illustrates an end view of the array of transducer elements shown in  FIG. 2B  along with illustrated ranges of angles of beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 3  illustrates three example arrays arranged to provide continuous sonar coverage utilizing beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 3A  illustrates a first array shown in  FIG. 3  along with its corresponding ranges of angles of beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 3B  illustrates a second array shown in  FIG. 3  along with its corresponding ranges of angles of beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 3C  illustrates a third array shown in  FIG. 3  along with its corresponding ranges of angles of beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 4  illustrates another example arrangement of three example arrays arranged to provide continuous sonar coverage utilizing beamformed sonar return beams, in accordance with some embodiments discussed herein; 
         FIG. 5  shows a perspective view of an example transducer assembly that includes three arrays, in accordance with some embodiments discussed herein; 
         FIG. 6  shows an exploded view of the example transducer assembly shown in  FIG. 5 , in accordance with some embodiments discussed herein; 
         FIG. 7  shows a bottom perspective view of another example transducer assembly that includes three arrays, in accordance with some embodiments discussed herein; 
         FIG. 8  illustrates a watercraft with an example transducer assembly utilizing three arrays to provide continuous sonar coverage, in accordance with some embodiments discussed herein; 
         FIG. 9  illustrates a schematic top plan view of the watercraft and sonar coverage shown in  FIG. 8 , in accordance with some embodiments discussed herein; 
         FIG. 10  shows an example marine electronic device presenting a two-dimensional (2D) live sonar image corresponding to the sonar coverage shown in  FIG. 8 , in accordance with some embodiments discussed herein; 
         FIG. 11  illustrates the arrangement of three example arrays shown in  FIG. 4 , wherein a downward sonar return beam is indicated, in accordance with some embodiments discussed herein; 
         FIG. 12  shows an example marine electronic device presenting a downward sonar image with high resolution, wherein the sonar image is formed from sonar return data from the downward sonar return beam indicated in  FIG. 11 , in accordance with some embodiments discussed herein; 
         FIG. 13  illustrates the arrangement of three example arrays shown in  FIG. 4 , wherein multiple sonar return beams are indicated, in accordance with some embodiments discussed herein; 
         FIG. 14  shows an example marine electronic device presenting a downward sonar image with fish arches, wherein the sonar image is formed from sonar return data from the multiple sonar return beams indicated in  FIG. 13 , in accordance with some embodiments discussed herein; 
         FIG. 15  shows an example marine electronic device presenting a downward sonar image with high resolution surface features and fish arches, wherein the sonar image is formed from sonar return data from both the one downward sonar return beam indicated in  FIG. 11  and the multiple sonar return beams indicated in  FIG. 13 , in accordance with some embodiments discussed herein; 
         FIG. 15A  shows an example marine electronic device presenting a split screen of a two-dimensional (2D) live sonar image and a downward sonar image with high resolution surface features and fish arches, in accordance with some embodiments discussed herein; 
         FIGS. 16A-B  illustrate example mounting options for the example transducer assembly of  FIG. 5  when mounted generally vertically, in accordance with some embodiments discussed herein; 
         FIG. 17  illustrates a watercraft with an example transducer assembly utilizing a single array to provide sonar coverage, in accordance with some embodiments discussed herein; 
         FIG. 18  illustrates the arrangement of the single example array shown in  FIG. 17 , wherein a downward sonar return beam is indicated, in accordance with some embodiments discussed herein; 
         FIG. 19  illustrates the arrangement of the single example array shown in  FIG. 17 , wherein multiple sonar return beams are indicated, in accordance with some embodiments discussed herein; 
         FIG. 20  illustrates a schematic top plan view of a watercraft with an example transducer assembly utilizing three arrays, wherein the transducer assembly is mounted horizontally to provide sonar coverage in the port-to-starboard direction in front of the watercraft, in accordance with some embodiments discussed herein; 
         FIG. 20A  shows an example marine electronic device presenting a two-dimensional (2D) live sonar image corresponding to the sonar coverage shown in  FIG. 20 , in accordance with some embodiments discussed herein; 
         FIGS. 21A-B  illustrate example mounting options for the example transducer assembly of  FIG. 5  when mounted generally horizontally, in accordance with some embodiments discussed herein; 
         FIG. 22  is a block diagram of an example sonar system, in accordance with some embodiments discussed herein; 
         FIG. 23  is a block diagram of another example sonar system, in accordance with some embodiments discussed herein; 
         FIG. 24  illustrates a flowchart of an example method of operating a sonar system according to some embodiments discussed herein; and 
         FIG. 25  illustrates a flowchart of another example method of operating a sonar system according to some embodiments discussed herein. 
     
    
    
     DETAILED DESCRIPTION 
     Exemplary embodiments of the present invention now will be described more fully hereinafter with reference to the accompanying drawings, in which some, but not all embodiments of the invention are shown. Indeed, the invention may be embodied in many different forms and should not be construed as limited to the exemplary embodiments set forth herein; rather, these embodiments are provided so that this disclosure will satisfy applicable legal requirements. Like reference numerals refer to like elements throughout. 
     As depicted in  FIG. 1 , a watercraft  100  (e.g., a vessel) configured to traverse a marine environment, e.g. body of water  101 , may use one or more sonar transducer assemblies  102   a ,  102   b , and  102   c  disposed on and/or proximate to the watercraft. The watercraft  100  may be a surface watercraft, a submersible watercraft, or any other implementation known to those skilled in the art. The transducer assemblies  102   a ,  102   b , and  102   c  may each include one or more transducer elements (such as in the form of the arrays described herein) configured to transmit sound waves into a body of water, receive sonar returns from the body of water, and convert the sonar returns into sonar return data. 
     Depending on the configuration, the watercraft  100  may include a main propulsion motor  105 , such as an outboard or inboard motor. Additionally, the watercraft  100  may include trolling motor  108  configured to propel the watercraft  100  or maintain a position. The one or more transducer assemblies (e.g.,  102   a ,  102   b , and/or  102   c ) may be mounted in various positions and to various portions of the watercraft  100  and/or equipment associated with the watercraft  100 . For example, the transducer assembly may be mounted to the transom  106  of the watercraft  100 , such as depicted by transducer assembly  102   a . The transducer assembly may be mounted to the bottom or side of the hull  104  of the watercraft  100 , such as depicted by transducer assembly  102   b . The transducer assembly may be mounted to the trolling motor  108 , such as depicted by transducer assembly  102   c.    
     The watercraft  100  may also include one or more marine electronic devices  160 , such as may be utilized by a user to interact with, view, or otherwise control various aspects of the various sonar systems described herein. In the illustrated embodiment, the marine electronic device  160  is positioned proximate the helm (e.g., steering wheel) of the watercraft  100 —although other places on the watercraft  100  are contemplated. Likewise, additionally or alternatively, a user&#39;s mobile device may include functionality of a marine electronic device. 
       FIGS. 2A-C  illustrate an example array  220  of transducer elements  208  that may be utilized with various embodiments of the present invention, such as within an example transducer assembly described herein. In some embodiments, the transducer array  220  may include a plurality of transducer elements  208  arranged in a line and electrically connected relative to each other. For example, the transducer elements  208  may be individually positioned on a printed circuit board (PCB). The PCB may mechanically support and electrically connect the electronic components, including the transducer elements using conductive tracks (e.g. traces), pads, and other features. The conductive tracks may comprise sets of traces; for example, each transducer elements may be mounted to the PCB such that the transducer element is in electrical communication with a set of traces. Each transducer element, sub-array, and/or the array of transducer elements may be configured to transmit one or more sonar pulses and/or receive one or more sonar return signals. Unless otherwise stated, although  FIGS. 2A-C  illustrate a linear array with transducer elements of a certain shape, different types of arrays (or sub-arrays), transducer elements, spacing, shapes, etc. may be utilized with various embodiments of the present invention. 
     In the illustrated embodiment shown in  FIG. 2A , the transducer array  220  includes an emitting face  221  with a length LA and a width WA, where the length is greater than the width. Within the array  220 , each transducer element  208  defines an emitting face  209  with a length LT and a width WT, where the length is greater than the width. The length of each transducer element  208  is perpendicular to the length of the emitting face  221 . Each transducer element  208  is spaced at a predetermined distance from an adjacent transducer element, which may be designed based on desired operating characteristics of the array  220 , such as described herein. 
     In some embodiments, the array  220  of transducer elements  208  is configured to operate to transmit one or more sonar beams into the underwater environment. Depending on the configuration and desired operation, different transmission types of sonar beams can occur. For example, in some embodiments, the array  220  may transmit sonar beams according to a frequency sweep (e.g., chirp sonar) so as to provide sonar beams into the underwater environment. In some embodiments, the array  220  may be operated to frequency steer transmitted sonar beams into various volumes of the underwater environment. In some embodiments, the array  220  may be operated to cause a broadband transmit sonar beam to be sent into the underwater environment. Depending on the frequency used and phase shift applied between transducer elements, different volumes of the underwater environment may be targeted. 
     In some embodiments, the array  220  may be configured to receive sonar return signals. The way the sonar return signals are received and/or processed may vary depending on the desired sonar system configuration.  FIGS. 2B-2C  illustrate the array  220  with example possible sonar return beam coverage according to various example embodiments. In this regard, in some embodiments, each of the plurality of transducer elements are configured to operate at a fixed phase shift (e.g., at one of 0°, π/2 radian, π/4 radian, or π/8 radian) and vary in frequency (e.g., between 500 kHz-1200 kHz). This processing approach beamforms multiple sonar return beams (e.g., beam  280 ) between a first range of angles (θ 1 )  281  and between a second range of angles (θ 2 )  282 . To explain, the sonar returns may be received by the array  220  and filtered into frequency bins based on the frequency of the signal. From that, sonar return beams  280  can be determined that provide sonar returns within a small angle window (e.g., 0.5° to 1°, although greater or lesser angle windows are contemplated). Since the mounting orientation with respect to the watercraft can be known, and the frequency is known, then the relative angle with respect to the waterline (or other reference) can be determined and used to form sonar imagery, as described herein. 
     With further reference to  FIG. 2B , the sonar return beams (e.g.,  280 ) can be “steered” (e.g., along arrow R) within the first range of angles  281  based on varying the frequency (e.g., between 291a and 291b). Likewise, the sonar return beams can be “steered” within the second range of angles  282  based on varying the frequency (e.g., between 292a and 292b). By operating the transducer elements at a fixed phase shift, the two range of angles  281 ,  282  can be covered with sonar beams, but there is also a gap (e.g., indicated by the range of angles ( 3 ) that is not able to be covered by the frequency steered sonar return beams. 
     Without being bound by theory, a perhaps simplified explanation of this can be based on considering a single beam shape that is formed by a receipt event of the array. The beam shape is formed of a rather wide main beam lobe, along with at least one relatively small defined side lobe (e.g., the beam  280 ) that extends outwardly therefrom. By operating at a fixed phase shift and ignoring the main beam lobe, the sonar return signals received within the side lobe can be determined. Further, changing the frequency causes a shifting of the direction of the side lobe among the range of angles ( 281  or  282 ). Since the side lobe is symmetrical about the main lobe, there are two ranges of angles that are symmetrical about the facing direction DFD of the emitting face  221  of the array  220 . 
     Further information regarding beamforming, including frequency steered beamforming, can be found, for example, in the following: U.S. Pat. No. RE45,379, entitled “Frequency Division Beamforming for Sonar Arrays”; U.S. Pat. No. 10,114,119, entitled “Sonar Systems using Interferometry and/or Beamforming for 3D Imaging”; U.S. Pat. No. 9,739,884, entitled “Systems and Associated Methods for Producing a 3D Sonar Image”; and U.S. patent application Ser. No. 16/382,639, published as U.S. Publication No. 2019/0265354, and entitled “Sonar Transducer Having Geometric Elements”; the contents of each hereby being incorporated by reference in their entireties. 
     Depending on various factors, different beam shapes can be achieved and different ranges of angles can be achieved. The following describes some example factors that can be varied to effect the beam shapes and different ranges of angles: the number of transducer elements, the size/shape of the transducer elements, the size/shape of the array, the fixed phase shift, the frequency range, among other things. An example embodiment produces a first range of angles spanning ˜22.5° and a second range of angles spanning ˜22.5° with a gap of range of angles of ˜45° therebetween. Additionally, sonar return beams of ˜0.5° to 1° are formed. Further, with reference to  FIG. 2C , a transverse beamwidth θ 3  of ˜20° is formed (although other transverse beamwidths are contemplated such as between ˜9° and 27°). Some example embodiments that may achieve such example beam shapes include an array length of between ˜100-150 mm; an array width of between ˜3-10 mm; an array thickness of between ˜1-3 mm; a number of transducer elements of between 50-200; a width of the transducer element of between ˜0.4-1 mm; and a length of the transducer element of between ˜2-10 mm (although outside of these ranges is also contemplated). 
     In some embodiments, the system may be configured to utilize more than one array, where the arrays are oriented relative to each other to increase coverage volume of the underwater environment. For example, in some embodiments, a second (or more) array(s) can be added and tilted relative to the first array such that the gap within the first array is “covered” by one or more of the range of angles of sonar return beams from such array(s).  FIG. 3  illustrates an example three array assembly  310  that is designed to provide continuous sonar coverage utilizing beamformed sonar return beams. The sonar assembly  310  includes a first array  340 , a second array  330 , and a third array  320 . The first array  340  (shown by itself in  FIG. 3A ), is oriented with a facing direction (e.g., substantially straight down relative to the figure) so as to produce a first range of angles  341  and a second range of angles  342  (with a gap in between). The second array  330  (shown by itself in  FIG. 3B ), is oriented with a facing direction at an angle (e.g., ˜22.5° relative to the facing direction of the first array  340 ) so as to produce a first range of angles  331  and a second range of angles  332  (with a gap in between). The third array  320  (shown by itself in  FIG. 3C ), is oriented with a facing direction at another angle (e.g., ˜45° relative to the facing direction of the first array  340 ) so as to produce a first range of angles  321  and a second range of angles  322  (with a gap in between). As so arranged, the gaps between each set of the two range of angles are covered by a range of angles from each of the other two arrays. The illustrated example thus provides continuous sonar beam coverage for ˜135°. 
       FIG. 4  illustrates another example transducer assembly  510  that includes an arrangement of three arrays arranged to provide continuous sonar coverage utilizing beamformed sonar return beams. Notably, while the first array  540  and the third array  520  are mounted and oriented similarly to the first and third arrays of the transducer assembly  310  of  FIG. 3 , the second array  530  of the transducer assembly  510  has been shifted (e.g., offset) while maintaining its relative angle orientation (e.g., it is still mounted with a facing direction at an angle (e.g., −22.5°) relative to the facing direction of the first array—just as in the transducer assembly  310 ). Thus, the transducer assembly  510  forms an “X” configuration for the first array  540  and the third array  520 , but also has a line “_” at the bottom of the “X” corresponding to the second array  530 . Notably, the same relative continuous sonar beam coverage is obtained (e.g., as the small relative shift from the centerpoint  315  in  FIG. 3  does not significantly change the resulting beam coverage—particularly with respect to the distance covered in the underwater environment). For explanatory purposes, the various ranges of angles are shown extending from a slightly revised centerpoint  515 . 
       FIG. 5  illustrates an example transducer assembly  602  including a housing  605  that houses the three arrays  620 ,  630 ,  640  (which are shown in exploded view in  FIG. 6 ). Notably, the housing  605  includes one or more mounting features (e.g., a ratchet-type mounting feature  604  for enabling secured attachment in different orientations). The cable  606  provides a safe channel for running various wires  607  used in conjunction with the arrays. Notably, the X plus line configuration of the arrays enables some benefits for the transducer assembly  602 . For example, the housing  605  of the transducer assembly  602  may maintain a small footprint and still provide a straight bottom that enables a user to more easily comprehend the position of the center array (and, thus, determine and orient the transducer assembly  602  properly with respect to the watercraft for the desired coverage). With reference to  FIG. 6 , the PCB  609  and the electrical connectors  603  are also shown for electrically connecting the arrays  620 ,  630 , and  640 .  FIG. 7  illustrates an example transducer assembly  602 ′ shown in an orientation that would provide similar beam coverage as shown in  FIG. 4 . 
       FIG. 8  illustrates a watercraft  100  with an example transducer assembly  702  utilizing three arrays to provide continuous sonar coverage  705  in the forward and downward directions relative to the watercraft  100 . In this regard, the three arrays work together to provide corresponding ranges of angles  721 ,  722 ,  731 ,  732 ,  741 ,  742 —similar to those shown and described with respect to  FIG. 4 . In the illustrated embodiments, the lengths of each of the emitting faces of the three arrays extends in the fore-to-aft direction of the watercraft. 
     As indicated herein, the frequency of the sonar return beams can be varied to provide a sonar return beam  706  that can sweep (e.g., along arrow A) within the sonar beam coverage  705  (e.g., across the three arrays)—to capture sonar return signals along the sonar beam coverage.  FIG. 9  illustrates the sonar beam coverage  705  from a top view (with the beam coverage  705  projected onto a seafloor). As illustrated the sonar return beam  706  would sweep (e.g., along arrow B) across the sonar beam coverage  705 . 
     In some embodiments, the transducer assembly can be used to form a live (or substantially real-time) two-dimensional (2D) sonar image (e.g., time/distance from the transducer assembly and angle). For example,  FIG. 10  illustrates a live 2D sonar image  780  presented on a display of a marine electronics device  760 . The live 2D sonar image  780  is formed as slices of sonar return data corresponding to each sonar return beam  786  extending within that sonar beam coverage (e.g., along arrow C). In this regard, the live 2D sonar image  780  can be updated in substantially real-time all at once as they were all received at substantially the same time (e.g., by selecting different frequencies to form all the different sonar return beams that are used to present sonar return data into the image at the proper angle). The reference distance from the transducer assembly  785  (e.g., which correlates to depth in the substantially straight down direction) is shown at  789 . An icon detailing the direction in which the transducer assembly is facing relative to the watercraft is shown at  787 . 
     In some embodiments, the transducer assembly can be used to form additional different-type sonar images, such as sonar images that anglers are used to seeing. For example, while the arrays provide complex transducer element arrangements that can be used to create the live 2D sonar image, some embodiments contemplate using the same transducer assembly to provide “waterfall” based (or one-dimensional (1D)) sonar images that build-up over time. Notably, the sonar system may select one or more of the sonar return beams to form the sonar images—all without other additional transducer elements. 
     In some embodiments, the sonar system may be configured to form high-definition 1D sonar images that build-up over time (e.g., across different sonar return receipts). As noted herein, each sonar return beam corresponds to an angle window (e.g., ˜0.5°-1°—although other angle windows are contemplated). By utilizing the sonar return beam (or a few sonar return beams) that corresponds to substantially straight down, the system can form a downward 1D sonar image with high definition. In this regard, the resulting beam shape (e.g., a fan shape) for one (or a few) sonar beam(s) being selecting would be relatively narrow in the fore-to-aft direction (e.g., within 0.5°-3°, preferably within 0.5°-1°) and relative wide in the port-to-starboard direction (e.g., within ˜10°-27°). Notably, additional sonar return beams being selected would increase the beamwidth in the fore-to-aft direction (e.g., making a 2° by 20° beam shape, etc.). In this regard, in some embodiments, more than one sonar return beam could be selected and still produce the desired downward 1D sonar image with high-definition. 
     Such a beam shape would produce high definition downscan sonar imagery that would show high detail structure, such as the bottom surface, trees, etc. In this regard, the resulting sonar image is equivalent to that produced by a linear downscan transducer—which is a sonar image that anglers have gotten used to using. Notably, however, the angler would not have to purchase a separate transducer assembly with the linear transducer. An example linear downscan transducer is further described in U.S. Pat. No. 8,300,499, entitled “Linear and Circular Downscan Imaging Sonar”, which is incorporated by reference herein in its entirety. 
       FIG. 11  illustrates the arrangement of the three example arrays used for the transducer assembly  710 . In the illustrated example, the sonar return beam  777  is shown, which is the sonar return beam that corresponds to an angle within a range of angles  741  of one of the arrays  720 —where the angle is substantially straight downward from the watercraft. In this regard, the determined sonar return beam  777  comes from the third array  720 . In some embodiments, the selected sonar return beam  777  may be pre-determined and utilized whenever a user wants to see the high-definition 1D sonar image, or it may be determined based on the orientation of the transducer assembly  710  (e.g., using an orientation sensor and determining the orientation of the transducer assembly with respect to a reference, such as the top surface of the body of water—e.g., waterline). In this regard, though the third array  720  included the indicated sonar return beam that corresponds to substantially straight down, in different orientations, the first or second array may instead include the appropriate sonar return beam. Further, as noted above, though one sonar return beam  777  is shown, more than one could be selected (e.g., three sonar return beams, such as one on each side of the shown sonar return beam  777 ). 
     Once determined (whether pre-determined or determined otherwise), the sonar system may be configured to generate a corresponding sonar image that utilizes sonar return data from the one or more sonar return beam. For example,  FIG. 12  shows an example marine electronic device  760  presenting a high-definition 1D (e.g., time/distance) downward sonar image  790 . Notably, the sonar image  790  builds up from right to left in a “waterfall” format (e.g., along arrow D) with each subsequent slice of sonar image portions  793  filling on the right side of the sonar image  790  and pushing the older slices to the left (e.g., from sonar return data taken at different, older times). Notably, detailed bottom surface  791  and underwater structure  792  (e.g., seaweed or underwater trees) are visible in the sonar image  790 . This is, in some embodiments, due to the small beam width used for each slice in the fore-to-aft direction. 
     In some embodiments, the sonar system may be configured to form 1D sonar images with desirable fish finding features (e.g., fish arches). Such an example sonar image would build-up over time (e.g., across different sonar return receipts). As noted herein, each sonar return beam corresponds to an angle window (e.g., ˜0.5°-1°—although other angle windows are contemplated). By utilizing a plurality of sonar return beams (e.g., a range of angles), where at least one corresponds to substantially straight down, the system can form a downward 1D sonar image with fish arches. In this regard, the resulting beam shape for a plurality of sonar beams being selecting may be relatively wide (e.g., above 10°) in both the fore-to-aft direction (e.g., within the range of ˜10°-45°, (preferably ˜20°-40°) and the port-to-starboard direction (e.g., within the range of ˜10°-27°). 
     Such a beam shape would produce fish arch images within the downscan sonar imagery that would be desirable for anglers. In this regard, the resulting sonar image is equivalent to that produced by a conical (or circular) downscan transducer—which is a sonar image that anglers have gotten used to using. Notably, however, the angler would not have to purchase a separate transducer assembly with the conical transducer. An example conical downscan transducer is further described in U.S. Pat. No. 8,300,499, entitled “Linear and Circular Downscan Imaging Sonar”, which is incorporated by reference herein in its entirety. 
       FIG. 13  illustrates the arrangement of the three example arrays used for the transducer assembly  710 . In the illustrated example, the plurality of sonar return beams  778  is shown selected (with a single one of the sonar return beams  779  also illustrated). In the illustrated embodiment, at least one of the selected sonar return beams with the plurality of sonar return beams  778  includes an angle within a range of angles  741  of one of the arrays  720 —where the angle is substantially straight downward from the watercraft. In the illustrated embodiment, the determined plurality of sonar return beams  778  comes from all three arrays  720 ,  730 ,  740 . This requires filtering frequencies across different arrays to then combine together to form the desired plurality of sonar return beams  778 . In some embodiments, less or different sonar return beams could be selected and only one or two arrays may be needed. In some embodiments, the selected plurality of sonar return beams  778  may be pre-determined and utilized whenever a user wants to see the 1D sonar image with fish arches, or it may be determined based on the orientation of the transducer assembly  710  (e.g., using an orientation sensor and determining the orientation of the transducer assembly with respect to a reference, such as the top surface of the body of water—e.g., waterline). In this regard, though the third array  720  included the indicated sonar return beam that corresponds to substantially straight down, in different orientations, the first or second array may instead include the appropriate sonar return beams. 
     In some embodiments, the selected plurality of sonar return beams (e.g., range of angles) may extend to both sides of the sonar return beam that corresponds to substantially straight down (e.g., 10° in the clockwise direction and 5° in the counter-clockwise direction, 10° in both directions, etc.). In some embodiments, the selected plurality of sonar return beams may be determined to include the sonar return beam with the angle corresponding to substantially straight down in the center. 
     Once determined (whether pre-determined or determined otherwise), the sonar system may be configured to generate a corresponding sonar image that utilizes sonar return data from the plurality of sonar return beams. For example,  FIG. 14  shows an example marine electronic device  760  presenting a 1D (e.g., time/distance) downward sonar image  795  with fish arches  797 . Notably, the sonar image  795  builds up from right to left in a “waterfall” format (e.g., along arrow E) with each subsequent slice of sonar image portions  798  filling on the right side of the sonar image  795  and pushing the older slices to the left (e.g., from sonar return data taken at different, older times). Notably, less-detailed bottom surface  796  along with the fish arches  797  are visible in the sonar image  795 . This is, in some embodiments, due to the wide beam width used for each slice in the fore-to-aft direction. 
     In some embodiments, the sonar system may be configured to form a desirable combination sonar image that includes both high-definition underwater structure (e.g., bottom surface and other structure) as well as desirable fish finding features (e.g., fish arches). Due to differing beam widths required to produce each sonar image feature, such a sonar image is not possible using just one beam width. In this regard, some embodiments of the present invention contemplate forming such a sonar image using example transducer assemblies that include one or more arrays, without the need for other transducer elements (e.g., a linear transducer element or a conical transducer element). 
     In this regard, in some embodiments, like the 1D sonar images described herein, such an example sonar image would also build-up over time (e.g., across different sonar return receipts). Further, however, both sets of determined sonar return beams would be utilized to gather sonar return data that is inputted together into the sonar image. For example, returning to  FIG. 11 , the sonar return beam  777  (or equivalent as described herein) would be selected for the high-definition features and, returning to  FIG. 13 , the plurality of sonar return beams  778  (or equivalent as described herein) would be selected for the fish arch features. As with the prior described sonar images, such sonar return beams could be pre-determined or determined otherwise (e.g., via an orientation sensor). Likewise, as described with respect to each of the example sonar return beam  777  and the plurality of sonar return beams  778 , more or less (or different) sonar return beams could be selected to achieve the desired sonar return data. 
     In some embodiments, the system could be configured to form the sonar image from both the one of the multiple sonar return beams (e.g., the sonar return beam  777 ) and the plurality of the multiple sonar beams (e.g., the sonar return beams  778 ). For example, the sonar system may form the sonar image from sonar image portions corresponding to each sonar return beam set, where the sonar image portions are then combined to form the sonar image. As an example, the system may determine one or more fish arches based on sonar return data from the plurality of sonar return beams (e.g., sonar return beams  778 ), form the sonar image portions of the fish arches, and then position them in appropriate positions (e.g., at the depth and time associated with the sonar return data of the fish arches) within the sonar image portions corresponding to the sonar return beam  777 . While this example describes fish arches, additional or other features (or depth portions) within the sonar return data from the plurality of sonar return beams could be used. 
     In some embodiments, the sonar system is configured to determine the fish arch from within sonar return data corresponding to the plurality of multiple sonar return beams that have been received across at least two or more time receipts. Such a determination could be performed using various filters or algorithms to distinguish between sonar return data that applies to fish (or fish-like objects)—e.g., using the strength of the sonar return, depth, relative position with respect to similar strength sonar returns, etc. In some embodiments, the image could be formed, and image recognition technology could be applied to identify the fish arch. In some embodiments, the fish arch may need to be of a certain size or shape threshold in order to qualify for use. For example,  FIG. 14  illustrates an example fish arch  797  that has a height HFA and a width WFA that can be determined to qualify. In some embodiments, the degree of arch may also be a factor for determining a qualifying fish arch. 
     With the fish arches identified, the sonar image may be formed by combining the sonar image portions corresponding to the fish arches with the sonar image portions corresponding to the sonar return data received by the sonar return beam  777 . For example, in some embodiments, the system is configured to generate the sonar image portion corresponding to the fish arch by removing or nullifying sonar image data (e.g., sonar return data formed into image compatible data) within the sonar return data that is not the determined fish arch. Alternatively, the system may form the sonar image portion of the fish arch only. 
     Once the fish arch image portion is formed, the system may position the fish arch appropriately within the remaining sonar image portion (from the plurality of sonar return beams). For example, the system may determine the depth and time associated with the sonar return data corresponding to the fish arch; and position the generated sonar image portion of the fish arch at the position within the sonar image portions corresponding to the plurality of sonar return beams (e.g., sonar return beams  778 ) at the determined depth and time. In some embodiments, the fish arch sonar image portions may be overlaid onto the remaining sonar image portions (from the plurality of sonar return beams). Additionally or alternatively, the fish arch sonar image portions may replace corresponding portions of the remaining sonar image portions (from the plurality of sonar return beams). 
     In some embodiments, the resulting combined sonar image could be generated a number of different ways using sonar return data corresponding to both the sonar return beam  777  and the plurality of sonar return beams  778 . For example, the sonar image could be formed by blending the sonar return data, including, in some embodiments, applying a greater weight to one set of the sonar return data. In some embodiments, a depth range of each sonar return data could be used. For example, the water column (from the watercraft to the bottom surface) could be used for the plurality of sonar return beams  778  (e.g., to show fish arches), while the bottom surface and below could be used for the sonar return beam  777  (e.g., to show the detail of the bottom surface). Slight variations in depth (e.g., the bottom surface plus 5 feet) could be used instead. 
       FIG. 15  shows an example marine electronic device  760  presenting a combined downward sonar image  718 . Notably, the sonar image  718  builds up from right to left in a “waterfall” format (e.g., along arrow F) with each subsequent slice of sonar image portions  713  filling on the right side of the sonar image  718  and pushing the older slices to the left (e.g., from sonar return data taken at different, older times). Notably, the combined sonar image  713  includes detailed bottom surface  711  and other underwater structure (e.g., from the single or a few sonar return beams, such as sonar return beam  777 ) as well as the fish arches  712  (e.g., from the plurality of sonar return beams, such as sonar return beams  778 ). Such an image provides the desirable high-definition structure along with desirable fish arches that anglers are used to—all in one sonar image. 
     In some embodiments, the system may be configured to present one or more of the four different sonar images described herein—all based on utilizing the same transducer assembly (with one or more arrays). In this regard, the user can simply select which of the sonar images to have presented, and they are swappable as the system may be generating the sonar images simultaneously in the background. In some embodiments, the sonar system may provide three sonar image possibilities: a 2D live sonar image such as shown and described in  FIG. 10 , a 1D downward sonar image with fish finding features such as shown and described in  FIG. 14 , and a downward sonar image with high resolution surface features and fish arches shown and described in  FIG. 15  (although in some embodiments the downward sonar image with high resolution features shown and described in  FIG. 12  may be toggled between with the downward sonar image with high resolution surface features and fish arches shown and described in  FIG. 15 ). In some embodiments, the system may be configured to present two or more such sonar images in split screen (or multiple screen) mode. For example,  FIG. 15A  shows an example marine electronic device  760  presenting a split screen of a two-dimensional (2D) live sonar image  780  and a downward sonar image with high resolution surface features and fish arches  718 . 
     In some embodiments, the transducer assembly may be mounted to different portions of the watercraft or its corresponding devices (e.g., a trolling motor, pole, etc.). For example,  FIG. 16A  illustrates the transducer assembly  802  mounted to a pole  810  (e.g., a shaft of a trolling motor) using a mounting arm  806 . The mounting arm  806  attaches via a fastener to the transducer assembly  802  at a first end  807  and to the pole  810  via a clamp  808  at a second end  805 . The mounting arm  806  includes a bend that enables the transducer assembly  802  to be spaced from the pole  810  and oriented as desired (e.g., facing generally downward along arrow G).  FIG. 16B  illustrates the transducer assembly  802  mounted to the trolling motor housing  812  via a strap and clamp  804 . The transducer assembly  802  may be oriented as desired (e.g., facing generally downward along the arrow G). 
     As detailed herein, in some embodiments, the system may be configured to provide similar functionality utilizing only a single array of transducer elements. In this regard, the system may be more cost effective for anglers and still provide desirable functionality. For example,  FIG. 17  illustrates a watercraft  100  with a transducer assembly  1002  that includes a single array that produces beam coverage as indicated by the first range of angles  1041  and the second range of angles  1042 . In this regard, the single array is mounted and oriented in a generally forward and downward facing direction. The sonar return beams  1006   a  and  1006   b  (when taken alone or in a plurality) can be used to form the various sonar images described herein. In this regard, like various arrays described herein, the sonar return beam  1006   a  can be frequency steered through the first range of angles  1041  (e.g., along arrow K), while the sonar return beam  1006   b  can be frequency steered through the second range of angles  1042  (e.g., along arrow L).  FIG. 18  illustrates the array  1040  of the transducer assembly  1002  with an example sonar return beam  1077  indicated, such as may be determined and/or used for various example sonar images, such as shown and described with respect to  FIGS. 13, 15, and 15A . Likewise,  FIG. 19  illustrates the array  1040  of the transducer assembly  1002  with an example plurality of sonar return beams  1078  indicated (with an example single sonar return beam  1079  indicated also), such as may be determined and/or used for various example sonar images, such as shown and described with respect to  FIGS. 14, 15, and 15A . 
     In some embodiments, the transducer assembly can be configured to be oriented differently to provide different sonar image options. For example, the transducer assembly may be configured to be oriented horizontally (such as pointing forward from the watercraft) and provide a desirable sonar image. In this regard, the extended sonar beam coverage (e.g., ˜135°) may be used to see a wider view in the port-to-starboard direction with respect to the watercraft (or off to one side of the watercraft or both sides if two transducer assemblies are used). 
       FIG. 20  illustrates a watercraft  100  with an example transducer assembly  902  utilizing three arrays to provide continuous sonar coverage  905  horizontally in the forward direction relative to the watercraft  100  (e.g., port-to-starboard). In this regard, the three arrays work together to provide corresponding ranges of angles  921 ,  922 ,  931 ,  932 ,  941 ,  942 —similar to those shown and described with respect to  FIG. 4 . In the illustrated embodiments, the lengths of each of the emitting faces of the three arrays extends in the port-to-starboard direction of the watercraft. As indicated herein, the frequency of the sonar return beams can be varied to provide a sonar return beam  906  that can sweep (e.g., along arrow H) within the sonar beam coverage  905  (e.g., across the three arrays)—to capture sonar return signals along the sonar beam coverage. With such an example set-up, the resulting 2D live sonar image would show a live (or near real-time) sonar image corresponding to the volume extending in front of the watercraft according to the beam coverage. 
     In some embodiments, the transducer assembly can be used to form a live (or substantially real-time) two-dimensional (2D) sonar image (e.g., time/distance from the transducer assembly and angle) with a horizontal view. For example,  FIG. 20A  illustrates a live 2D sonar image  727  presented on a display of a marine electronics device  760 . The live 2D sonar image  727  is formed as slices of sonar return data corresponding to each sonar return beam extending within that sonar beam coverage extending from the transducer assembly location  728 . In this regard, the live 2D sonar image  727  can be updated in substantially real-time all at once as they were all received at substantially the same time (e.g., by selecting different frequencies to form all the different sonar return beams that are used to present sonar return data into the image at the proper angle). The detailed bottom surface is shown at  729 . 
     In some embodiments, the transducer assembly may be mounted to different portions of the watercraft or its corresponding devices (e.g., a trolling motor, pole, etc.). For example,  FIG. 21A  illustrates the transducer assembly  902  mounted to a pole  910  (e.g., a shaft of a trolling motor) using a mounting arm  906 . The mounting arm  906  attaches via a fastener to the transducer assembly  902  at a first end  907  and to the pole  910  via a clamp  908  at a second end  905 . The mounting arm  906  includes a bend that enables the transducer assembly  902  to be spaced from the pole  910  and oriented as desired (e.g., facing generally forward along arrow J).  FIG. 21B  illustrates the transducer assembly  902  mounted to the trolling motor housing  912  via a strap and clamp  904 . The transducer assembly  902  may be oriented as desired (e.g., facing generally forward along the arrow J). 
     Example System Architecture 
       FIG. 22  shows a block diagram of an example sonar system  400  of various embodiments of the present invention described herein. The illustrated sonar system  400  includes a marine electronic device  405  and a transducer assembly  462 , although other systems and devices may be included in various example systems described herein. In this regard, the system  400  may include any number of different systems, modules, or components; each of which may comprise any device or means embodied in either hardware, software, or a combination of hardware and software configured to perform one or more corresponding functions described herein. 
     The marine electronic device  405  may include a processor  410 , a memory  420 , a user interface  435 , a display  440 , one or more sensors (e.g. position sensor  445 , other sensors  447 , etc.), and a communication interface  430 . One or more of the components of the marine electronic device  405  may be located within a housing or could be separated into multiple different housings (e.g., be remotely located). 
     The processor  410  may be any means configured to execute various programmed operations or instructions stored in a memory device (e.g., memory  420 ) such as a device or circuitry operating in accordance with software or otherwise embodied in hardware or a combination of hardware and software (e.g. a processor operating under software control or the processor embodied as an application specific integrated circuit (ASIC) or field programmable gate array (FPGA) specifically configured to perform the operations described herein, or a combination thereof) thereby configuring the device or circuitry to perform the corresponding functions of the processor  410  as described herein. In this regard, the processor  410  may be configured to analyze electrical signals communicated thereto to provide or receive sonar data, sensor data, location data, and/or additional environmental data. For example, the processor  410  may be configured to receive sonar return data, generate sonar image data, and generate one or more sonar images based on the sonar image data. 
     In some embodiments, the processor  410  may be further configured to implement sonar signal processing, such as in the form of a sonar signal processor (although in some embodiments, portions of the processor  410  or the sonar signal processor could be located within the transducer assembly  462 ). In some embodiments, the processor  410  may be configured to perform enhancement features to improve the display characteristics or data or images, collect or process additional data, such as time, temperature, GPS information, waypoint designations, or others, or may filter extraneous data to better analyze the collected data. It may further implement notices and alarms, such as those determined or adjusted by a user, to reflect depth, presence of fish, proximity of other vehicles, e.g. watercraft, etc. 
     In an example embodiment, the memory  420  may include one or more non-transitory storage or memory devices such as, for example, volatile and/or non-volatile memory that may be either fixed or removable. The memory  420  may be configured to store instructions, computer program code, marine data, such as sonar data, chart data, location/position data, and other data associated with the navigation system in a non-transitory computer readable medium for use, such as by the processor for enabling the marine electronic device  405  to carry out various functions in accordance with example embodiments of the present invention. For example, the memory  420  could be configured to buffer input data for processing by the processor  410 . Additionally or alternatively, the memory  420  could be configured to store instructions for execution by the processor  410 . 
     The communication interface  430  may be configured to enable connection to external systems (e.g. an external network  402 ). In this manner, the marine electronic device  405  may retrieve stored data from a remote device  461  via the external network  402  in addition to or as an alternative to the onboard memory  420 . Additionally or alternatively, the marine electronic device may transmit or receive data, such as sonar signals, sonar returns, sonar image data or the like to or from a transducer assembly  462 . In some embodiments, the marine electronic device  405  may also be configured to communicate with other devices or systems (such as through the external network  102  or through other communication networks, such as described herein). For example, the marine electronic device  405  may communicate with a propulsion system of the watercraft  100  (e.g., for autopilot control); a remote device (e.g., a user&#39;s mobile device, a handheld remote, etc.); or other system. 
     The marine electronic device  405  may also include one or more communications modules configured to communicate with one another in any of a number of different manners including, for example, via a network. In this regard, the communications module may include any of a number of different communication backbones or frameworks including, for example, Ethernet, the NMEA 2000 framework, GPS, cellular, WiFi, or other suitable networks. The network may also support other data sources, including GPS, autopilot, engine data, compass, radar, etc. In this regard, numerous other peripheral devices (including other marine electronic devices or transducer assemblies) may be included in the system  400 . 
     The position sensor  445  may be configured to determine the current position and/or location of the marine electronic device  405  (and/or the watercraft  100 ). For example, the position sensor  445  may comprise a global positioning system (GPS), bottom contour, inertial navigation system, such as machined electromagnetic sensor (MEMS), a ring laser gyroscope, or other location detection system. 
     The display  440 , e.g. one or more screens, may be configured to present images and may include or otherwise be in communication with a user interface  435  configured to receive input from a user. The display  440  may be, for example, a conventional LCD (liquid crystal display), a touch screen display, mobile device, or any other suitable display known in the art upon which images may be displayed. 
     In some embodiments, the display  440  may present one or more sets of marine data (or images generated from the one or more sets of data). Such marine data includes chart data, radar data, weather data, location data, position data, orientation data, sonar data, or any other type of information relevant to the watercraft. In some embodiments, the display  440  may be configured to present such marine data simultaneously as one or more layers or in split-screen mode. In some embodiments, a user may select any of the possible combinations of the marine data for display. 
     In some further embodiments, various sets of data, referred to above, may be superimposed or overlaid onto one another. For example, a route may be applied to (or overlaid onto) a chart (e.g. a map or navigational chart). Additionally or alternatively, depth information, weather information, radar information, sonar information, or any other navigation system inputs may be applied to one another. 
     The user interface  435  may include, for example, a keyboard, keypad, function keys, mouse, scrolling device, input/output ports, touch screen, or any other mechanism by which a user may interface with the system. 
     Although the display  440  of  FIG. 22  is shown as being directly connected to the processor  410  and within the marine electronic device  405 , the display  440  could alternatively be remote from the processor  410  and/or marine electronic device  405 . Likewise, in some embodiments, the position sensor  445  and/or user interface  435  could be remote from the marine electronic device  405 . 
     The marine electronic device  405  may include one or more other sensors  447  configured to measure or sense various other conditions. The other sensors  447  may include, for example, an air temperature sensor, a water temperature sensor, a current sensor, a light sensor, a wind sensor, a speed sensor, or the like. 
     The transducer assembly  462  illustrated in  FIG. 22  includes three transducer arrays  467 ,  468 , and  469 . In some embodiments, more or less transducer arrays could be included or other transducer elements could be included. As indicated herein, the transducer assembly  462  may also include a sonar signal processor or other processor (although not shown) configured to perform various sonar processing. In some embodiments, the processor (e.g., processor  410  in the marine electronic device  405 , a processor (or processor portion) in the transducer assembly  462 , or a remote processor—or combinations thereof) may be configured to filter sonar return data and/or selectively control transducer elements of the transducer arrays. For example, various processing devices (e.g., a multiplexer, a spectrum analyzer, A-to-D converter, etc.) may be utilized in controlling or filtering sonar return data and/or transmission of sonar signals from the arrays  467 ,  468 ,  469 . 
     The transducer assembly  462  may also include one or more other systems, such as various sensor(s)  466 . For example, the transducer assembly  462  may include an orientation sensor, such as gyroscope or other orientation sensor (e.g., accelerometer, MEMS, etc.) that can be configured to determine the relative orientation of the transducer assembly  462  and/or the various arrays  467 ,  468 ,  469 —such as with respect to a waterline, the top surface of the body of water, or other reference. In some embodiments, additionally or alternatively, other types of sensor(s) are contemplated, such as, for example, a water temperature sensor, a current sensor, a light sensor, a wind sensor, a speed sensor, or the like. 
       FIG. 23  shows a block diagram of another example sonar system  400 ′ of various embodiments of the present invention described herein. The illustrated sonar system  400 ′ includes the same various components and devices as the system  400  shown and described with respect to  FIG. 22 , but instead of three transducer arrays, the system  400 ′ includes a single transducer array  467 ′ in the transducer assembly  462 ′. Such an example transducer assembly  462 ′ with a single transducer array  467 ′ may correspond to various embodiments herein, such as some example embodiments shown and described with respect to  FIGS. 17-19 . 
     Example Flowchart(s) and Operations 
     Embodiments of the present invention provide methods, apparatus and computer program products for operating a sonar system according to various embodiments described herein. Various examples of the operations performed in accordance with embodiments of the present invention will now be provided with reference to  FIGS. 24-25 . 
       FIG. 24  illustrates a flowchart according to example methods for operating a sonar system according to an example embodiment. The operations illustrated in and described with respect to  FIG. 24  may, for example, be performed by, with the assistance of, and/or under the control of one or more of the processor  410 , memory  420 , communication interface  430 , user interface  435 , position sensor  445 , other sensor  447 , transducer assembly  462 ,  462 ′, display  440 , and/or external network  402 /remote device  461 . The method  500  may include operating one or more arrays to transmit sonar signals into the underwater environment at operation  502 . At operation  504 , the method comprises receiving sonar return data from the one or more arrays. Then, at operation  506 , the sonar return data is filtered to beamform multiple sonar return beams. At operation  508 , the method may include determining downward sonar return beams for forming high-resolution 1D sonar imagery. The method may further include determining downward sonar return beams for forming fish arches at operation  510 . Finally, at operation  512 , the method may include forming sonar images with high resolution sonar portions and fish arches, such as described herein. In some embodiments, the method may include additional, optional operations, and/or the operations described above may be modified or augmented, such as in accordance with various example embodiments described herein. 
       FIG. 25  illustrates a flowchart according to example methods for operating a sonar system according to another example embodiment. The operations illustrated in and described with respect to  FIG. 25  may, for example, be performed by, with the assistance of, and/or under the control of one or more of the processor  410 , memory  420 , communication interface  430 , user interface  435 , position sensor  445 , other sensor  447 , transducer assembly  462 ,  462 ′, display  440 , and/or external network  402 /remote device  461 . The method  600  may include operating one or more arrays to transmit sonar signals into the underwater environment at operation  602 . At operation  604 , the method comprises receiving sonar return data from the one or more arrays. Then, at operation  606 , the sonar return data is filtered to beamform multiple sonar return beams. At operation  608 , the method may include forming a 2D live sonar image using the multiple sonar return beams. At operation  610 , the method may further include forming a downward sonar image with high resolution using one or more downward sonar return beams, such as described herein. At operation  612 , the method may further include forming a downward sonar image with fish arches using a plurality of downward sonar return beams, such as described herein. In some embodiments, the method may include additional, optional operations, and/or the operations described above may be modified or augmented, such as in accordance with various example embodiments described herein. 
       FIGS. 24-25  illustrate flowcharts of a system, method, and computer program product according to an example embodiment. It will be understood that each block of the flowcharts, and combinations of blocks in the flowcharts, may be implemented by various means, such as hardware and/or a computer program product comprising one or more computer-readable mediums having computer readable program instructions stored thereon. For example, one or more of the procedures described herein may be embodied by computer program instructions of a computer program product. In this regard, the computer program product(s) which embody the procedures described herein may be stored by, for example, the memory  420  and executed by, for example, the processor  410 . As will be appreciated, any such computer program product may be loaded onto a computer or other programmable apparatus (for example, a marine electronic device  405 ) to produce a machine, such that the computer program product including the instructions which execute on the computer or other programmable apparatus creates means for implementing the functions specified in the flowchart block(s). Further, the computer program product may comprise one or more non-transitory computer-readable mediums on which the computer program instructions may be stored such that the one or more computer-readable memories can direct a computer or other programmable device (for example, a marine electronic device  405 ) to cause a series of operations to be performed on the computer or other programmable apparatus to produce a computer-implemented process such that the instructions which execute on the computer or other programmable apparatus implement the functions specified in the flowchart block(s). 
     CONCLUSION 
     Many modifications and other embodiments of the inventions set forth herein will come to mind to one skilled in the art to which these inventions pertain having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is to be understood that the embodiments of the invention are not to be limited to the specific embodiments disclosed and that modifications and other embodiments are intended to be included within the scope of the invention. Moreover, although the foregoing descriptions and the associated drawings describe example embodiments in the context of certain example combinations of elements and/or functions, it should be appreciated that different combinations of elements and/or functions may be provided by alternative embodiments without departing from the scope of the invention. In this regard, for example, different combinations of elements and/or functions than those explicitly described above are also contemplated within the scope of the invention. Although specific terms are employed herein, they are used in a generic and descriptive sense only and not for purposes of limitation.