Systems and associated methods for producing a 3D sonar image

The invention claimed is: 1. A sonar system comprising: a housing mountable to a watercraft capable of traversing a body of water; a transmit transducer element positioned within the housing and configured to transmit first sonar pulses into the water; at least one sidescan transducer array positioned within the housing and at least downwardly from the watercraft, wherein the sidescan transducer array comprises a first sidescan transducer element and a second sidescan transducer element, wherein the first sidescan transducer element is configured to transmit second sonar pulses into the water, receive first sonar returns from the first sonar pulses produced by the transmit transducer element and convert sound energy of the first sonar returns into first sonar return data, wherein the second sidescan transducer element is configured to receive second sonar returns from the first sonar pulses produced by the transmit transducer element and convert sound energy of the second sonar returns into second sonar return data, wherein at least one of the first sidescan transducer element or the second sidescan transducer element is configured to receive sidescan sonar returns from the second sonar pulses produced by the first sidescan transducer element and convert sound energy of the sidescan sonar returns into sidescan sonar return data, and wherein the first sidescan transducer element is positioned within the housing at a predetermined distance from the second sidescan transducer element; and a sonar signal processor configured to: process the first sonar return data and the second sonar return data to generate 3D mesh data based on at least the predetermined distance between the first sidescan transducer element and the second sidescan transducer element, wherein the 3D mesh data is a basis for a 3D image of an underwater environment in a three dimensional coordinate system; process the sidescan sonar return data to generate sidescan image data; and generate 3D image data representing the 3D image based on the 3D mesh data and the sidescan image data. 2. The sonar system of claim 1 further comprising a display configured to display the 3D image of an underwater environment based at least on the 3D image data. 3. The sonar system of claim 2 , wherein the display is configured to display the 3D image of the underwater environment based on the 3D image data and a sidescan image of the underwater environment based on the sidescan image data in a split screen format. 4. The sonar system of claim 2 , wherein the display is configured to display the 3D image of the underwater environment based on the 3D image data and chart information in a split screen format. 5. The sonar system of claim 1 , wherein the sonar signal processor is further configured to generate the 3D image data by matching a position associated with the sidescan image data with a corresponding position associated with the 3D mesh data. 6. The sonar system of claim 1 , wherein the sonar signal processor is further configured to generate the 3D image data by combining the sidescan image data and the 3D mesh data. 7. The sonar system of claim 1 , wherein the sonar signal processor is further configured to generate the 3D image data by overlaying the sidescan image data on the 3D mesh data. 8. The sonar system of claim 1 , wherein the sonar signal processor is further configured to remove sidescan sonar returns associated with a water column from the sidescan image data prior to generating the 3D image data based on the 3D mesh data and the sidescan image data. 9. The sonar system of claim 1 , wherein the sonar signal processor is further configured to: process the first sonar return data and the second sonar return data to generate a set of 2D sonar data, wherein each sonar return of the set of 2D sonar data defines a distance value and an angle, wherein the angle associated with each sonar return is based on the predetermined distance between the first sidescan transducer element and the second sidescan transducer element, wherein the distance value associated with each sonar return corresponds to a distance between a position of the sonar return and the at least one sidescan transducer array; and generate the 3D mesh data based on the set of 2D sonar data. 10. The sonar system of claim 9 , wherein the sonar signal processor is further configured to: generate a plurality of sets of 2D sonar data as the watercraft traverses the body of water; and generate the 3D mesh data based on the plurality of sets of 2D sonar data. 11. The sonar system of claim 10 , wherein the sonar signal processor is further configured to: generate a plurality of sets of sidescan sonar return data as the watercraft traverses the body of water; and generate the sidescan image data based on the plurality of sets of sidescan sonar return data. 12. The sonar system of claim 1 , wherein the transmit transducer element is configured to transmit the first sonar pulses at a first frequency, wherein the first sidescan transducer element is configured to transmit the second sonar pulses at a second frequency, wherein the first frequency is different than the second frequency. 13. The sonar system of claim 12 , wherein the first frequency is approximately 600 kHz and the second frequency is approximately 480 kHz. 14. The sonar system of claim 1 , wherein the first sidescan transducer element and the second sidescan transducer element are configured to receive the first sonar return data and the second sonar return data, respectively, simultaneously with the at least one first sidescan transducer element or second sidescan transducer element receiving the sidescan sonar return data. 15. The sonar system of claim 1 , wherein the sidescan transducer array is a first sidescan transducer array aimed downwardly and outwardly from a first side of the watercraft, wherein the sonar system further comprises: a second sidescan transducer array positioned within the housing and aimed downwardly and outwardly from a second side of the watercraft, wherein the second side of the watercraft is generally opposite to the first side of the watercraft, wherein the second sidescan transducer array comprises a third sidescan transducer element and a fourth sidescan transducer element, wherein the third sidescan transducer element is configured to transmit third sonar pulses into the water, receive third sonar returns from the first sonar pulses produced by the transmit transducer element, and convert sound energy of the third sonar returns into third sonar return data, wherein the fourth sidescan transducer element is configured to receive fourth sonar returns from the first sonar pulses produced by the transmit transducer element and convert sound energy of the fourth sonar returns into fourth sonar return data, wherein at least one of the third sidescan transducer element or the fourth sidescan transducer element is configured to receive second sidescan sonar returns from the third sonar pulses produced by the third sidescan transducer element and convert sound energy of the second sidescan sonar returns into second sidescan sonar return data, and wherein the third sidescan transducer element is positioned within the housing at a predetermined distance from the fourth sidescan transducer element; and wherein the sonar signal processor is further configured to: process the third sonar return data and the fourth sonar return data to generate the 3D mesh data based on at least the second predetermined distance between the third sidescan transducer element and the fourth sidescan transducer element