A marine sonar display device comprises a display, a sonar element, a memory element, and a processing element. The display presents sonar images. The sonar element generates a sonar beam and presents transducer signals. The processing element is in communication with the display, the sonar element, and the memory element and receives the transducer signals, calculates sonar data from the transducer signals and generates a three-dimensional view of a portion of the body of water, wherein the view includes a plurality of sonar images. Each sonar image is generated from sonar data derived from a previously-generated sonar beam and includes representations of underwater objects and a water bed. The processing element also generates a cursor plane and a cursor positioned thereon, both of which appear on the three-dimensional view. The processing element further controls the display to present the three-dimensional view, the sonar images, the cursor plane, and the cursor.

Techniques are disclosed for systems and methods to provide networkable sonar systems for mobile structures. A networkable sonar system includes a transducer module and associated sonar electronics and optionally orientation and/or position sensors and/or other sensors disposed substantially within the housing of a sonar transducer assembly, which is coupled to one or more user interfaces and/or other sonar systems over an Ethernet connection. The sonar transducer assembly may be configured to support and protect the transducer module and the sonar electronics and sensors, to physically and/or adjustably couple to a mobile structure, and/or to provide a simplified interface to other systems coupled to the mobile structure. Resulting sonar data and/or imagery may be transmitted over the Ethernet connection and displayed to a user and/or used to adjust various operational systems of the mobile structure.

An obstacle detection apparatus for vehicles includes: a first ultrasonic sensor for detecting a distance to an obstacle; a second ultrasonic sensor at a position of the vehicle for receiving a reflection wave from the obstacle of an ultrasonic wave from the first ultrasonic wave; a notifier that gives a notification of detecting the obstacle present within a preset distance in one or more of predetermined notification areas including a first notification area for the first ultrasonic sensor, and a second notification area for the second ultrasonic sensor detects the obstacle for the vehicle; and a controller that controls contents to be notified by the notifier. Furthermore, the controller determines whether a first indirect wave distance and a second indirect wave distance are used to determine whether to give the notification of detecting the obstacle in the first notification area.

An obstacle detection apparatus for vehicles includes: a first ultrasonic sensor for detecting a distance to an obstacle; a second ultrasonic sensor at a position of the vehicle for receiving a reflection wave from the obstacle of an ultrasonic wave from the first ultrasonic wave; a notifier that gives a notification of detecting the obstacle present within a preset distance in one or more of predetermined notification areas including a first notification area for the first ultrasonic sensor, and a second notification area for the second ultrasonic sensor detects the obstacle for the vehicle; and a controller that controls contents to be notified by the notifier. Furthermore, the controller determines whether a first indirect wave distance and a second indirect wave distance are used to determine whether to give the notification of detecting the obstacle in the first notification area.

Overlaying a sonar image over a chart at a corresponding location can provide a beneficial and easy to understand view of the underwater environment for a user. However, in some cases, the watercraft may be close to a boundary of the body of water when the sonar data is gathered. In such a scenario, inaccurate sonar returns or preset display distances of the sonar image can cause the resulting sonar image to be displayed over the boundary and covering land. This can be confusing and can be difficult to decipher. Embodiments of the present invention provide systems and methods for cropping the sonar image for presentation over the chart such that no portion of the image extends beyond the boundary line of the body of water. This creates a smooth and easy to read sonar image/chart display.

A method for providing enhanced sonar images includes ensonifying a target column of water with sonar beams corresponding to pulses of continuous wave (CW) and pulse compression (FM) signals. Received acoustic returns are processed to generate sonar image data corresponding to the CW signals and the FM signals. The CW and FM sonar image data are then displayed contemporaneously such that one sonar image data set overlays another. Techniques are also disclosed to provide situational imagery. A pilot display system includes a user interface, a logic device, and a speed sensor mounted to a mobile structure. The user interface is configured to receive user input and provide user feedback, and the logic device is configured to receive a speed of the mobile structure from the speed sensor, generate corresponding situational image data, and render the situational image data via at least one display of the user interface.

Provided are a sonar system and transducer assembly for producing a 3D image of an underwater environment. The sonar system may include a housing mountable to a watercraft having a transmit transducer that may transmit sonar pulses into the water. The system may include at least one sidescan transducer array in the housing that receives first and second sonar returns with first and second transducer elements and converts the first and second returns into first and second sonar return data. A sonar signal processor may then generate a 3D mesh data using the first and second sonar return data and at least a predetermined distance between the transducer elements. An associated method of using the sonar system is also provided.

Systems and methods for providing a sonar beam footprint are detailed herein. A system for presenting marine data includes at least one sonar transducer associated with a watercraft, a display, processor(s), and memory including computer program code. The sonar transducer emits sonar beams into an underwater environment that define a beam shape. The program code, when executed, causes, on the display, presentation of a chart and a representation of the watercraft; determines a depth corresponding to a bottom surface of a body of water at a current location of the watercraft; and determines, based on the depth and the beam shape, a sonar beam footprint corresponding to a projection of the beam shape at the depth. The program code further causes, on the display, presentation of the sonar beam footprint on the chart so as to visually indicate sonar beam coverage.

A system and method are provided for visualizing an offset in static parameters in an echo sounding system by generating a difference grid by subtracting a first survey line from a second survey line to determine difference values at each point in the grid; and displaying the difference grid on a display device, where the difference values are represented on a visual scale. The difference values may be used to calibrate the echo sounding system or check the quality of the calibration of an echo sounding system.

An integrated fish detection module/navigation module system that may provide the location of fish over a distance or time is provided herein. The location of fish can be presented on a navigation module display to provide information regarding the location of fish relative to navigational data known to the navigation module. The information may create a record of fish location over time and distance. In some configurations, the navigational data and fish detection module data of more than one watercraft may be combined and distributed. In some configurations, a marker may be automatically placed on a navigation module to indicate that fish have been detected at the location on the navigation module.