NZ786470A - Automatic navigation of a marine environment area - Google Patents
Automatic navigation of a marine environment areaInfo
- Publication number
- NZ786470A NZ786470A NZ786470A NZ78647022A NZ786470A NZ 786470 A NZ786470 A NZ 786470A NZ 786470 A NZ786470 A NZ 786470A NZ 78647022 A NZ78647022 A NZ 78647022A NZ 786470 A NZ786470 A NZ 786470A
- Authority
- NZ
- New Zealand
- Prior art keywords
- determined
- water
- watercraft
- route
- marine
- Prior art date
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- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract 35
- 238000004590 computer program Methods 0.000 claims abstract 11
- 230000000875 corresponding Effects 0.000 claims abstract 8
- 229940035295 Ting Drugs 0.000 claims 2
- 235000015076 Shorea robusta Nutrition 0.000 claims 1
- 150000002500 ions Chemical class 0.000 claims 1
Abstract
Systems and methods for automatic navigation of a marine environment area are detailed herein. A system for navigating a marine area includes a display, a processor, and a memory including a computer program code. The computer program code, when executed, causes, on the display, presentation of a chart including at least a portion of a body of water; receives an input of at least one condition parameter associated with the desired marine environment; determines a portion of the body of water defined by the at least one condition; and displays the determined portion on the chart. The computer program code further, when executed, determines a traversal coverage corresponding to a watercraft; and determines a route to traverse the determined portion based on the traversal coverage of the watercraft such that an entirety of the determined portion is covered by the determined traversal coverage of the watercraft during the route. art including at least a portion of a body of water; receives an input of at least one condition parameter associated with the desired marine environment; determines a portion of the body of water defined by the at least one condition; and displays the determined portion on the chart. The computer program code further, when executed, determines a traversal coverage corresponding to a watercraft; and determines a route to traverse the determined portion based on the traversal coverage of the watercraft such that an entirety of the determined portion is covered by the determined traversal coverage of the watercraft during the route.
Description
AUTOMATIC TION OF A MARINE ENVIRONMENT AREA
This ation claims priority from United States patent application ,492,
filed 31 March 2021, the entire content of which is incorporated by reference.
FIELD OF THE INVENTION
Embodiments of the present invention relate generally to navigating a marine
environment, and more particularly, to providing for navigation of a marine nment that
satisfies specific conditions of interest.
BACKGROUND OF THE INVENTION
tional systems, such as marine navigational systems, may provide a display of
a navigational chart or map. Nautical navigation charts including electronic or interactive
al charts are typically used to provide a user with information about a body of water
including (but not limited to) depth, routes, water temperatures, or the like. Some nautical charts
may also provide an indication of the current location of a watercraft (e.g., vessel) associated
with the display device. Further, some electronic nautical charts may also display the location,
course, speed and/or other information for one or more other watercrafts on the body of water.
Routes may be displayed in association with the navigational chart and may be followed by
manual maneuvering of the watercraft or by an autopilot system.
BRIEF SUMMARY OF THE INVENTION
As noted above, navigational s are capable of collecting, compiling, and
storing various data about marine navigation and marine events. Anglers and boaters may know
conditions of the marine environment they are looking for (e.g., temperature of the water or
depths), but the marine environment may not be easily ascertainable by looking through all the
data.
It is an object of at least preferred ments to address at least some of the
aforementioned antages. An onal or alternative object is to at least provide the public
with a useful choice.
Embodiments of the present invention enable determination of a portion of a body of
water defined by condition parameters input by a user. In some cases, however, the marine
environment defined by the d condition parameters may be an arbitrary shape which may
be difficult to navigate effectively and/or efficiently. As such, ments of the present
invention create navigation routes to traverse the determined portion of the body of water (e.g.,
the desired marine environment). The navigation routes may be based on a traversal coverage,
which may be determined by the user or determined by characteristics of the watercraft,
including a width of the watercraft, a determined fishing cast distance, a width of a towed g
line, or based on a sonar beam footprint. ingly, a marine data system (e.g., utilizing the
navigational system) may calculate a route to automatically navigate the desired marine
environment, such as without prompting the user to create or accept a particular search pattern.
In some embodiments, the marine data system may take into account and/or
determine desired speeds of the watercraft, turn capabilities, and/or additional user inputs to
determine the navigation route. In some embodiments, the marine data system may suggest or
highlight condition parameters to increase or decrease the desired marine environment to be
ted. In some embodiments, the system may suggest navigating outside of the marine
environment for efficiency of the route.
Using a traversal coverage provides the marine data system with a metric to
determine a route based on the navigable area to effectively cover the entire determined portion
of the marine environment, such that although the watercraft may not ly pass along the
entirety of the marine environment, the determined portion is effectively covered by the
ions and characteristics (e.g., various s, sonars, etc.) of the watercraft.
In an example embodiment, a marine data system is provided including a display, a
processor, and a memory including a computer program code. The computer program code is
configured to, when executed by the processor, cause, on the display, tation of a chart
including at least a portion of a body of water. The computer program code is r configured
to receive user input indicating at least one condition parameter associated with a desired marine
environment within the body of water. The er program code is further configured to
determine a portion of the body of water that is d by the at least one condition parameter
and cause, on the display, presentation of an indication of the determined n of the body of
water on the chart. The tation of the indication of the determined n includes
highlighting a portion of the body of water on the chart representing the determined portion. The
computer program code is further configured to determine a traversal coverage ponding to
the watercraft, and determine a route, based on the determined traversal coverage, to traverse the
determined portion such that an ty of the determined portion is covered by the determined
traversal coverage of the watercraft in an instance in which the watercraft traverses the
ined route.
In some embodiments, the traversal coverage is based on a sonar beam footprint of a
sonar transducer of the watercraft. The sonar beam footprint corresponds to a projection of a
beam shape of one or more sonar beams of the sonar ucer at a determined depth. In some
embodiments, the determined depth corresponds to the bottom surface of the body of water.
In some embodiments, the computer program code is further configured to cause, on
the display, presentation of a representation of the determined traversal coverage on the chart
relative to a current position of the watercraft.
In some embodiments, the computer program code is r configured to cause, on
the display, presentation of a trail indicating historical positions of the watercraft along the
ined route. In some embodiments, the trail includes a representation of the determined
sal coverage so as to indicate which part of the determined portion has been covered by the
determined route.
In some embodiments, the determined traversal coverage is a selected width.
In some embodiments, the ined traversal coverage is based on at least one of a
width of the watercraft, a width corresponding to a fishing cast distance, or a width
corresponding to a towed g line.
In some embodiments, the ined route is configured to ze the number of
turns by the watercraft.
In some embodiments, the determined route includes maneuvering outside of the
ined portion so as to minimize turns by the watercraft.
In some embodiments, the determined route does not include turns that are greater
than 75°.
In some ments, the computer program code is further configured to cause an
autopilot to cause the watercraft to traverse the determined route.
In some embodiments, data corresponding to the at least one condition parameter is
gathered from at least one of a global positioning system (GPS), satellite data, navigation data,
prior track data, or server data.
In some embodiments, the at least one condition parameter includes a range of
estimated or determined water temperatures within a range of water depths.
In some ments, the er program code is further configured to calculate a
time of se. The time of traverse is based on a speed of the watercraft and the determined
route to traverse the determined portion. In some embodiments, the computer program code is
further configured to cause, on the y, an indication of the time of traverse.
In some ments, the route is further determined by a determined desired speed
of traversal of the watercraft.
In some embodiments, the ined portion of the body of water includes a
plurality of ct portions of the body of water. The plurality of distinct portions of the body of
water include a first distinct portion of the body of water, and a second distinct portion of the
body of water. The first distinct portion of the body of water is ted from the second distinct
portion of the body of water by a third portion of the body of water that does not satisfy the at
least one condition parameter. The determined route ses between the first distinct portion
of the body of water and the second distinct portion of the body of water so as to traverse the
entirety of the determined plurality of the distinct portions of the body of water.
In some embodiments, the computer program code is further configured to cause, on
the display an indication of the determined route.
In some embodiments, the computer program code is further configured to determine
an adjusted portion of the body of water. The adjusted portion of the water is defined by, in
comparison to the determined n, at least one of a different range of the at least one
ion parameter or the at least one condition parameter and an additional parameter. The
computer program code is further configured to cause, on the display, presentation of an
indication of the adjusted portion.
In another example embodiment a method for presenting marine data is provided. The
method comprises g, on a display, a presentation of a chart including at least a portion of a
body of water. The method includes receiving user input indicating at least one condition
parameter associated with a desired marine environment within the body of water. The method
includes determining, via a processor, a portion of the body of water that is defined by the at
least one condition parameter and causing, on the y, presentation of an tion of the
determined portion on the chart. The presentation of the indication of the determined portion
includes highlighting a portion of the body of water representing the determined portion. The
method includes determining, via the processor, a traversal coverage corresponding to a
watercraft, and further determining, via the processor, a route based on the determined traversal
coverage, to traverse the ined portion, such that an entirety of the determined portion is
covered by the determined traversal coverage of the watercraft in an ce in which the
watercraft traverses the determined route.
The term ‘comprising’ as used in this specification means ‘consisting at least in part
of’. When interpreting each ent in this specification that includes the term ‘comprising’,
features other than that or those prefaced by the term may also be t. Related terms such as
‘comprise’ and ‘comprises’ are to be reted in the same manner.
In yet another example embodiment, a non-transitory er-readable medium
having stored thereon a plurality of computer-executable ctions, which, when executed by a
processor, cause the processor to cause, on a display, presentation of a chart including at least a
portion of a body of water. The instructions further cause the processor to determine at least one
condition parameter associated with a desired marine environment within the body of water, and
determine a portion of the body of water that is d by the at least one condition parameter.
The ctions further cause the processor to cause, on the display, presentation of an tion
of the determined portion on the chart. The presentation of the indication of the determined
portion includes highlighting a portion of the body of water on the chart representing the
determined portion. Finally, the instructions further cause the processor to determine, a traversal
coverage corresponding to a watercraft, and determine a route, based on the determined traversal
ge, to traverse the determined portion such that an entirety of the ined portion is
covered by the determined traversal coverage of the watercraft in an instance in which the
watercraft traverses the determined route.
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:
illustrates an example watercraft including various marine devices, in
accordance with some embodiments discussed herein;
illustrates an e display presenting a chart, in accordance with some
embodiments sed herein;
illustrates the example display presenting the chart, with an example input
screen for enabling a user to input a minimum condition parameter, in accordance with some
embodiments discussed ;
illustrates the e display presenting the chart, with an example input
screen for enabling the user to input a maximum condition parameter, in accordance with some
embodiments discussed herein;
illustrates the example display presenting the chart, with an e
ghted determined portion, where the determined portion is defined by the condition
parameter(s), in accordance with some embodiments discussed herein;
rates the e display presenting the chart, wherein an example
suggested portion of the body of water is highlighted, wherein the suggested portion is defined
by an example suggested condition parameter, in accordance with some embodiments discussed
herein;
illustrates the example display presenting the chart, wherein another e
suggested portion of the body of water is highlighted, wherein the suggested portion is defined
by another example suggested condition parameter, in ance with some embodiments
discussed herein;
illustrates the example display presenting the chart, wherein a user-selected
portion of the body of water is highlighted, in accordance with some embodiments discussed
herein;
illustrates the example display presenting the chart, n an example
route to traverse the determined portion of the body of water is presented, in accordance with
some embodiments bed herein;
illustrates the example display presenting the chart, n another example
route to se the determined portion of the body of water is presented, in accordance with
some embodiments described ;
illustrates the example display ting the chart, wherein an example trail
of traversal coverage at historical positions of the watercraft is presented, in accordance with
some embodiments discussed herein;
rates the example display presenting the chart, wherein an example route
to traverse two distinct portions of the body of water which include the condition parameter(s) is
presented, in accordance with some embodiments discussed herein;
illustrates a block m of an example system with various electronic
devices, marine devices, and secondary devices shown, in accordance with some embodiments
discussed herein; and
-13 illustrate flowcharts of example methods for determining a navigation
route for traversing a ined portion of a body of water, in ance with some
embodiments discussed herein.
ED DESCRIPTION
Example embodiments of the present invention now will be described more fully
hereinafter with reference to the accompanying gs, 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 example embodiments set forth
; rather, these embodiments are provided so that this disclosure will satisfy applicable legal
requirements. Like reference numerals refer to like elements throughout.
illustrates an example watercraft 100 including various marine devices, in
accordance with some ments discussed herein. As depicted in the watercraft 100
is configured to traverse a marine nment, e.g. body of water 101, and may use one or more
sonar transducer assemblies 102a, 102b, and 102c disposed on and/or proximate to the
watercraft. Notably, example watercraft contemplated herein may be e watercraft,
submersible watercraft, or any other implementation known to those skilled in the art. The
transducer assemblies 102a, 102b, and 102c may each include one or more transducer elements
configured to transmit sound waves into a body of water, receive sonar returns from the body of
water, and t the sonar returns into sonar return data. Various types of sonar transducers
may be provided — for example, a linear downscan sonar transducer, a conical downscan sonar
transducer, a sonar transducer array, an assembly with multiple transducer arrays, or a sidescan
sonar ucer may be used.
Depending on the uration, the raft 100 may include a primary motor 105,
which may be a main propulsion motor such as an outboard or inboard motor. Additionally, the
watercraft 100 may include a trolling motor 108 configured to propel the watercraft 100 or
maintain a on. The one or more transducer assemblies (e.g., 102a, 102b, and/or 102c) may
be d 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 ucer assembly 102a. The
transducer assembly may be mounted to the bottom or side of the hull 104 of the raft 100,
such as depicted by transducer ly 102b. The transducer assembly may be mounted to the
trolling motor 108, such as depicted by transducer assembly 102c.
The watercraft 100 may also e one or more marine electronic devices 160, such
as may be utilized by a user to interact with, view, or otherwise control various functionality
regarding the raft, including, for example, al charts and 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 raft 100 — although other places on the
watercraft 100 are contemplated. Likewise, additionally or alternatively, a remote device (such
as a user’s mobile device) may include functionality of a marine electronic device.
The watercraft 100 may also comprise other ents within the one or more
marine electronic devices 160 or at the helm. In the watercraft 100 comprises a radar
116, which is mounted at an elevated position (although other positions relative to the watercraft
are also contemplated). The watercraft 100 also comprises an AIS transceiver 118, a direction
sensor 120, and a camera 122, and these components are each oned at or near the helm
(although other positions relative to the watercraft are also contemplated). In other
embodiments, these components may be integrated into the one or more electronic devices 160
or other devices. Another example device on the watercraft 100 es a temperature sensor
112 that may be positioned so that it will rest within or e of the body of water 101. Other
example s include a wind sensor, one or more speakers, and various watercraft
devices/features (e.g., doors, bilge pump, fuel tank, etc.), a towed fishing line or other
attachments, among other things. Additionally, one or more sensors may be associated with
marine devices; for example, a sensor may be provided to detect the position of the primary
motor 105, the trolling motor 108, etc.
illustrates an example display 200, such as on a marine electronic device (e.g.,
160 in or the display 340 of the marine electronic device 305 shown in presenting
a chart 202. The chart 202 may present a body of water 204, and distinguish the water 204, from
land 206. The chart 202 may include a representation of a watercraft 208 at a current location
within the chart 202 (e.g., such may be determined based on position data). As rated,
watercraft 208 may have a relative size, such as may correspond to the zoom level of the chart
202, and a direction that may indicate in which direction the watercraft 208 is pointing (e.g., may
be based on ation data or recent/current position data). The chart 202 may further include
depth readings, such as may be pre-stored and/or may be updated based on various incoming
data (e.g., tidal data, sonar data, satellite data, etc.). In some embodiments, the chart 202 may be
stored in memory and/or gathered via an external or al network. The position and/or
orientation of the watercraft 208 may be determined by position and/or orientation data, such as
from a global oning system (GPS), her sources.
In some embodiments, the chart may present prior tracks from either the watercraft or
other rafts. The prior tracks may be presented on the chart and may also be used to t
data about the depth, water temperature, sonar imagery, wind, tides, other weather related data,
and other data of the marine environment associated with the prior tracks. illustrates two
tracks, 210a and 210b, wherein each of the tracks 210a and 210b represent a different route and
contain data about the marine nment traversed along the route.
In some embodiments, the chart may include data associated with the current location
of the raft, including a current position, depth reading, current speed, transducer gs,
headings, and/or other associated data. The chart may further include a selection screen 213 for
implementing various functionality, such as toggling between charts, creating new tracks,
indicated desired determined areas, among many other things. The display may be r
configured to present, and/or cease presenting various data, as described above, from the chart.
Further, the system may be configured to zoom in and zoom out on various points of the chart,
and adjust the relative size of the watercraft, tracks, and other presented data accordingly.
The chart 202 includes position data 212 of the watercraft 208 in the form of
nates. The chart 202 includes a selection screen 213 to toggle between views of the chart,
adjust and change the presentation of the tracks 210a, 210b, and other chart options.
In some embodiments, the system is configured to receive condition parameter inputs
to define a portion of the body of water a user would like to view and/or navigate . The
chart may include a condition parameter tab on a side of the chart wherein condition parameters
may be input. In some embodiments, a single condition parameter is used, while in other
embodiments multiple condition parameters may be used. Condition parameters may include
water temperature, water depth, water current patterns, air temperatures, and/or other parameters
which are readily available through prior tracks, navigation charts, s, GPS, satellite,
weather services, or other sources of data available on the watercraft. In some embodiments, the
system may only use one source of data, while in other embodiments the system may use
multiple sources of data. The ion parameters may require a minimum and maximum value
to form a range, or they system may have a preprogramed tolerance such that only a desired
value is selected. In some embodiments, the user may select a single condition parameter to
define the desired conditions of the marine environment, while in other embodiments a user may
define multiple ion parameters to define the conditions of the desired marine environment.
For example, in some embodiments the system may account for a minimum and a maximum
temperature, while in other ments the system may additionally account for a minimum
and a maximum water depth (e.g., the system looks for where the temperature falls within a
certain temperature range and the bottom surface falls within a certain depth range). In some
embodiments, the system may ine a minimum and maximum depth, allowing a user to
navigate within the desired depths.
In some embodiments, the system may take into account the time, day, season, etc.
for determining the portion of the body of water. In some embodiments, the system may just use
the current time/day. In some embodiments, system may enable user input to provide the d
time/day for determining the n of the body of water, such as may be useful for planning
ahead.
illustrates the display 200 presenting the chart 202, with an e input
screen 214 indicating the condition parameter ed is a minimum temperature. The input
screen 214 may be presented after a user selects a corresponding input for generation of an area,
such as in the selection screen 213. The input screen 214 ts a keypad 216, and plus and
minus keys 218 such that a user may input the parameter directly or adjust the condition
parameter incrementally (although other forms of input are plated, such as audible
commands, remote commands, etc.). rates, a follow up example input screen 214’
presented on the display 200 for a condition parameter of a maximum ature. Once the
condition parameter(s) is selected, the system may determine a portion of the body of water 204
defined by the condition parameter(s) of the desired marine environment.
illustrates the display 200 presenting the chart 202 and displaying the
determined portion 220 of the body of water, defined by the condition parameters 222. While the
determined portion 220 is shown in highlighted form in , various embodiments
contemplate other visualization options for presentation of the determined portion 220. For
example, the determined portion 220 may be presented in one or more colors, one or more
patterns, and/or other distinguishing visualization options. Likewise, ent levels of
transparency may be utilized. In some embodiments the chosen condition parameter(s) 222 may
be shown on the chart 202. Although presented in the bottom corner of the chart 202, it should be
understood the chosen condition ter(s) 222 may be presented on any acceptable part of
the chart 202, while in some ments the chosen condition parameter(s) 222 may not be
presented on the chart 202.
In some ments, the system may suggest changes to the condition parameters,
such as to increase or decrease the size of the determined portion defined by the initial input
condition parameters. In some embodiments, the system may determine the original determined
portion is too large to navigate. The system may prompt the user for an additional parameter, or
the system may t an additional parameter. In other embodiments, the system may
ine that the al determined portion is too constrained, and the system may suggest a
revised condition parameter(s) to e the determined portion, while in other embodiments the
system may prompt the user to revise or remove a ion parameter(s). In some embodiments,
the system may display the adjusted portion in a different highlight than the original determined
portion as to distinguish between the marine environment having the original condition
parameter(s), and the marine environment having the changed condition parameter(s), while in
other embodiments the adjusted portion may be shown without the original determined portion.
illustrates an e embodiment wherein the system determines the
determined portion 220 may be too large (e.g., too large to navigate, may include hazardous
portions, etc.). As illustrated in , the display 200 presents the chart 202 and the originally
determined portion 220 and its corresponding condition parameters 222. onally, however,
the system may suggest an onal condition parameter 224 (e.g., “Min. depth: 12 m”) to
suggest that the user add the condition ter 224 to further define the portion based on
having a minimum depth of 12 m. ingly, the display 200 includes a smaller adjusted
portion 226 to help the user visualize what the smaller portion would look like. The smaller
adjusted portion 226 is presented in a highlighted, pattern form to distinguish it from the original
determined portion 220, although other distinguishing visualizations are contemplated.
illustrates an example embodiment wherein the system determines that the
determined portion 220 may be too small. illustrates the display 200 presenting the chart
202 including the determined portion 220 and its ponding condition parameters 222. In
this e, the display suggests an adjustment to the prior inputted condition parameters 228
(e.g., adjust the lower temperature from 14 Celsius to 13 Celsius). ingly, the display 200
presents an example adjusted determined portion 230 (additions to the original portion 220
shown in highlighted, pattern form). In some embodiments, the adjusted condition parameters
228 may be predetermined by the system. In some embodiments, the system may prompt the
user to change the condition parameters 222.
While the smaller adjusted n 226 and the larger adjusted portion 230 are shown
in patterned form in FIGS. 4B-4C, various embodiments contemplate other visualization options
for the presentation of the adjusted portions 226, 230. For example, the adjusted ns 236,
230 may be presented in one or more colors, one or more patterns, and/or other distinguishing
visualization options. Likewise, different levels of transparency may be utilized.
In further embodiments, the system may e multiple condition parameter ranges.
The system may determine the portion of the body of water 204 defined by each parameter and
display each portion in a different ght, so as to visually indicate to a user where the
ion parameters p. A user may then choose a portion on the y which
corresponds to the condition parameters defining the desired marine area to be traversed. Once
the portion is chosen, the system may present the chosen condition parameters on the y
similarly to the embodiments presented in FIGS. 4A-4C.
In some embodiments, the system may search the entire body of water 206 for the
desired ion parameters, while in other embodiments a user may select a region 232 of the
body of water to navigate, such as shown in In some embodiments, a user may choose a
region 232 of the water by drawing a shape, using prior recorded tracks, contour lines or other
method of reducing the body of water to search. As shown in a region 232 has been
selected by choosing a n bounded by two prior tracks 210a and 210b, ing in a region
232 that is smaller than the body of water 204. Once the region 232 is selected, a user may input
condition parameters 222 into the system and result a determined n 220’ of the body of
water to navigate.
Once the system determines the portion of the body of water which meets the
ion parameters, the system may determine a route to traverse the determined portion. illustrates an embodiment of the present disclosure wherein the system calculates a route 234,
such that the watercraft 208 traverses the entirety of the ined portion 220. In some
embodiments, the watercraft may be in a location within the determined portion 220, and the
system may use the present on of the watercraft as the starting point to determine the
traversal route. While in other embodiments, the watercraft may be d outside of the
determined portion, in such an embodiment, the system may determine a route to the determined
portion (which may be part of the overall determined .
In some embodiments, the route 234 may be based on a traversal coverage 236 of the
watercraft 208. The traversal coverage 236 may have a size and/or shape, such as may be defined
by a width W1 and a length L1. In some embodiments, the traversal coverage may be determined
by the system. For example, the traversal coverage may be based on user inputs and/or
determined based on various factors. In this regard, in some embodiments, the traversal coverage
may be based on a length and/or width of the watercraft, a distance of a fishing cast, ions
of one or more towed fishing lines, sonar coverage of sonar ucers of the watercraft, or
other features corresponding to the watercraft.
In some embodiments, the traversal coverage 236 may be determined based on the
sonar coverage of a sonar transducer throughout the ined portion. In some embodiments,
this may correspond to a sonar beam footprint. A sonar beam footprint may be a projection of the
sonar beam, of a sonar transducer (e.g. 102a, 102b, & 102c of onto a bottom surface of
the body of water at a current on of watercraft. The sonar beam footprint may account for
many factors including, the transducer shape (or shape of the ng face(s) of the transducer,
the number of transducers, the configuration of how the transducer(s) operate, the direction the
ucer(s) are facing relative to the watercraft, the relative location of the transducer(s) on the
watercraft, the depth of the bottom surface at the current location, the frequency of operation,
etc. In some embodiments, the system may be configured to determine and account for at least
some of the various factors to ine and provide an indication to a user of the sonar
coverage at the specific location.
In some ments, the system may also be configured to determine the sonar
beam shape configured to emit from one or more sonar transducers. The beam shape may be
predetermined and stored in memory for the system to determine it therefrom. In some
embodiments, the system may account for more than one sonar transducer, and the relative
position of the mounting of each of the transducer(s) may also be accounted for. Alternatively,
in some embodiments, a central mounting on the watercraft may be assumed.
The sonar beam footprint may correspond to a flat projection of the beam shape of a
sonar transducer onto the bottom surface of the underwater on. Notably, however, the depth
to the bottom surface can affect the size of the sonar beam footprint even though the shape of the
sonar beam does not change. In this regard, the same sonar beam will cover a greater e
area of the bottom surface when the bottom surface is r away from the transducer (e.g., the
bottom surface is at a greater .
In some embodiments, the system may determine the sonar beam footprint has a
shape with certain dimensions, such as W1 and L1 (although any dimensional characteristics may
be determined and/or used to describe the determined sonar beam footprint). For example,
diameter (or radius) could be ined for the sonar beam footprint.
In some embodiments, the system may determine the sonar beam footprint at a
starting location of the watercraft, and set the initial sonar beam footprint as the traversal
coverage to determine the route of traverse of the determined portion, while in other
embodiments the system may account for a changing sonar beam int, or traversal coverage,
across the traversal route.
As illustrated in the representation of the watercraft 208 may have a relative
size, such as may pond to the zoom level of chart 202, and a direction, that may be
indicated by the direction that the watercraft 208 is pointing (e.g., such as may be based on
orientation data or current/recent position data). Additionally, the depth at the current location
may be displayed as an icon corresponding to the representation of the watercraft 208,
alternatively, the chart 202 may also include depth readings such as may be ored and/or
may be updated based on various ng data (e.g., tidal data, sonar data, satellite data, etc.).
With the traversal coverage determined, in some embodiments, the system may be
configured to provide a visual indication of the traversal coverage to the user. For e, the
system may cause presentation of the traversal coverage 236 on the display 200, such as via an
overlay on the chart 202 at the current location. The presentation of the traversal coverage 236
may be relative to the representation of the watercraft 208 so as to ly indicate the traversal
coverage relative to the watercraft 208 and the determined portion 220. For example,
depicts an example embodiment with the traversal coverage 236 in the shape of a circle with a
width W1 and a length L1 presented with the representation of the watercraft 208 within the
determined n 220 at the current location. Accordingly, a user can quickly visualize the
traversal coverage 236 at the current location.
While the traversal coverage 236 is shown in highlighted form in , various
embodiments contemplate other visualization options for the presentation of the traversal
coverage. For example, the traversal coverage may be presented in one or more colors, one or
more patterns, and/or other distinguishing visualization options. Likewise, ent levels of
transparency may be utilized.
In some ments, the system may determine a route 234 utilizing the determined
portion and the traversal coverage. In some embodiments, the system may account for onal
parameters. In some embodiments, the system may account for characteristics of the watercraft
208 when determining the route 234. For example, the system may consider a turn radius of the
watercraft (e.g., 15 ft., etc.), the number and ) of motors associated with the watercraft, a
d speed of traverse, and/or other similar characteristics. For example, in some
embodiments the system may determine the route such that the watercraft does not make a turn
which is greater than a threshold angle, such as 75 degrees. In some embodiments, the system
may be configured to receive additional user data on route preferences. For example, the system
may minimize the number of turns on the route, allow for traverse outside of the determined
portion, allow se only within the determined n, allow for backtracking, minimize the
time of traverse, determine a traversal speed and/or other similar s.
In some embodiments, the system may determine that the watercraft 208 includes
le motors (e.g., a trolling motor (e.g., 108 in and a primary motor (e.g., 105 in
). The system may be configured to use different motors during different parts of the
determined route. For example, returning to the system may be configured to use a
trolling motor, so as to se at a slower speed along a portion of the route (e.g., along a
portion of the route 234a within the determined portion), while the system may utilize a main
motor, so as to traverse at a higher speed along a portion of the route (e.g., a portion of the route
234b outside of the determined portion). Although two motors are referred to in this example
embodiment, other motor configurations are considered to allow the raft to traverse at
different speeds along different portions of the route 234.
The system may be configured to determine a time of traverse 238 for the determined
route 234 and may, in some embodiments, be configured to cause presentation of the calculated
time of traverse 238 on the chart 202. The time of traverse 238 may be based on the determined
route 234, and the determined speed(s) of traverse. In some embodiments, the system may
determine the route such that the time of traverse is minimized.
Returning to in some embodiments, the system may be ured to display
the route 234 on the chart 202 as an overlay of the determined portion 220. In some
embodiments, the presentation of the route 234 may include ion indicators 240 to indicate
to the user the direction of se of the watercraft 208 though the determined n 220. In
some embodiments, a portion of the route 234a within the determined portion may be presented
in a different color as a n of the route 234b outside of the ined portion, while in
other embodiments the route 234 (including the route within the determined portion 234a and the
route outside of the determined portion 234b) may be presented in a single color. Although a
color is indicated in this embodiment, other identifying presentations, ing highlights, line
patterns, arencies, etc. may be used to identify the route or portions thereof.
illustrates another example route 234’ for traversing the determined portion 220. The example
route 234’ includes a time of traverse of 87 minutes (shown at 238’).
In some embodiments, the traversal coverage 236 is presented in relation to the
watercraft 208 at a starting point of the route 236 such as to e the user with a visualization
of the traversal coverage 236. In other embodiments the traversal coverage 236 is not presented
on the chart 202, and only the route 234 in relation to the determined portion 220 is presented.
In some embodiments, with reference to the traversal coverage 236 may be
presented on the chart 202 as the watercraft 208 progresses along the route 234 so as to visually
indicate to a user the portion of the ined portion 220 covered by the watercraft 208. In
this regard, in some embodiments, the system may be configured to present a trail of the sal
coverage as the watercraft travels. In this regard, a user can easily visualize which parts of the
body of water have been d by the route, and which parts have not been covered.
illustrates an e traversal coverage trail 248. The traversal coverage trail 248 may include a
presentation of the route 234 traveled from the starting location to the present location of the
watercraft 208.
The system may also be configured to receive a user input to mark a point of the route
234, such as within the traversal coverage trail 248. The user input may mark a point of interest
including a fish, a school of fish, a structure or similar.
In some embodiments, a user may ine based on the presented route 234, and/or
the time of traversal 238, that the route parameters, and/or the condition parameters 222 require
an adjustment. A user may adjust the determined portion 220, by changing the ion
parameters, or manually adjusting the determined portion 220, and requesting the system to
ine a new route. In some embodiments the system may display the new route on the chart,
and cease presenting the prior route 234 on the chart 202 while in other embodiments the system
may t the new route in an overlaid fashion on the determined route 234.
In some embodiments, the system may engage an autopilot to traverse along the route
234 to cover the entire determined portion 220. In some embodiments the autopilot may be
configured to switch between speeds, and/or motors as required by the route, or as ted by
the user.
In some embodiments, the system may determine more than one distinct portion of
the body of water d by the input condition parameter(s). Referring now to the
system may determine a first distinct portion 242, and a second distinct portion 244, both d
by the desired ion parameter(s) 222, and separated by a third portion of the body of water
246 that is not defined by the desired condition parameter(s) 222. In some embodiments, the
system may determine a route within the first distinct portion, and then a second route within the
second distinct portion, while in other embodiments, as shown in the system may
determine a route 234 which traverses n the first distinct portion 242 and the second
distinct portion 244 by traversing the third portion 246.
The system may be configured such that the autopilot is engaged when traversing the
first distinct portion 242, the second distinct portion 244, and the third portion 246. In some
embodiments, the system may be configured to traverse at a first speed while sing the first
and second distinct portions 242, 244, and traverse at a second speed when traversing within the
third portion, or along parts of the route located outside of the first or second distinct portion. In
some ments, the first speed is slower than the second speed. In some embodiments the
first and second distinct portions are traversed using a trolling motor, while the third n may
be sed using a primary motor or by increasing the speed of the trolling motor. In some
ments, the system may display one or more condition parameter(s) corresponding to the
third portion on the screen and prompt the user to determine if the third portion should be
included in the determined portion as to combine the first ct portion, the second distinct
portion and the third portion into a single determined portion to be traversed in the entirety.
Although shows a first and a second distinct portion, there may be any number
of distinct portions which meet the ied condition parameter(s). In an example embodiment
where there are multiple distinct portions, the system may prompt for and/or utilize a user input
the includes an additional condition parameter(s), reduces the range of the given condition
parameter(s), defines a region to search, and/or selects one or more of the distinct portions to
include within the route.
Example System Architecture
illustrates a block diagram of an example system 300 according to various
embodiments of the t invention bed herein. The illustrated system 300 includes a
marine electronic device 305. The system 300 may comprise numerous marine devices. As
shown in one or more sonar transducer assemblies 362 may be provided. A radar 356, a
rudder 357, a primary motor 358, a trolling motor 359, and additional sensors/devices 360 may
also be provided as marine devices, but other marine s may be provided as well. One or
more marine devices may be implemented on the marine electronic device 305. For example, a
position sensor 345, a ion sensor 348, an autopilot 350, and other sensors 352 may be
provided within the marine electronic device 305. These marine devices can be integrated within
the marine electronic device 305, integrated on a watercraft at another location and connected to
the marine electronic device 305, and/or the marine devices may be implemented at a remote
device 354 in some ments. The system 300 may include any number of ent
systems, modules, or ents; each of which may comprise any device or means ed
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 305 may include at least one processor 310, a memory
320, a communication interface 330, a user interface 335, a display 340, autopilot 350, and one
or more sensors (e.g. position sensor 345, direction sensor 348, other sensors 352). One or more
of the components of the marine electronic device 305 may be located within a housing or could
be separated into multiple different housings (e.g., be remotely located).
The processor(s) 310 may be any means configured to execute various programmed
operations or instructions stored in a memory device (e.g., memory 320) such as a device or
try operating in accordance with software or otherwise embodied in hardware or a
combination of re and software (e.g. a processor operating under software l or the
processor embodied as an ation specific integrated circuit (ASIC) or field mmable
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 at least one processor 310 as described . For example, the at least one
processor 310 may be configured to analyze various data, such as for determining a portion of a
body of water that satisfies one or more condition parameters.
In some embodiments, the at least one processor 310 may be further configured to
implement signal processing. In some embodiments, the at least one processor 310 may be
ured to perform enhancement features to improve the display characteristics of data or
images, collect or process additional data, such as time, temperature, GPS information, waypoint
designations, or , or may filter extraneous data to better analyze the collected data. The at
least one processor 310 may further implement notices and alarms, such as those determined or
adjusted by a user, to reflect proximity of other objects (e.g., represented in sonar data), to t
proximity of other vehicles (e.g. watercraft), approaching storms, etc.
In an e embodiment, the memory 320 may include one or more non-transitory
storage or memory devices such as, for e, volatile and/or non-volatile memory that may
be either fixed or removable. The memory 320 may be configured to store instructions, er
program code, sonar data, and onal data such as radar data, chart data, location/position
data in a non-transitory computer readable medium for use, such as by the at least one processor
310 for enabling the marine electronic device 305 to carry out various functions in accordance
with e embodiments of the present invention. For example, the memory 320 could be
configured to buffer input data for processing by the at least one processor 310. Additionally or
alternatively, the memory 320 could be configured to store instructions for execution by the at
least one processor 310.
The ication interface 330 may be configured to enable communication to
external systems (e.g. an external network 302). In this manner, the marine electronic device
305 may retrieve stored data from a remote device 354 via the external network 302 in addition
to or as an alternative to the onboard memory 320. Additionally or alternatively, the marine
onic device 305 may transmit or receive data, such as sonar signal data, sonar return data,
sonar image data, or the like to or from a sonar transducer assembly 362. In some embodiments,
the marine electronic device 305 may also be configured to communicate with other devices or
systems (such as through the external network 302 or through other communication networks,
such as described herein). For example, the marine electronic device 305 may communicate
with a propulsion system of the watercraft 100 (e.g., for autopilot control); a remote device (e.g.,
a user’s mobile device, a handheld remote, etc.); or another system. Using the external network
302, the marine electronic device may icate with and send and receive data with external
sources such as a cloud, server, etc. The marine electronic device may send and e various
types of data. For e, the system may receive weather data, data from other fish locator
applications, alert data, among others. However, this data is not required to be communicated
using external network 302, and the data may instead be communicated using other approaches,
such as through a physical or wireless connection via the communications interface 330.
The communications interface 330 of the marine electronic device 305 may also
include one or more communications modules configured to icate with one another in
any of a number of different manners including, for example, via a network. In this regard, the
communications interface 330 may e any of a number of different communication
backbones or frameworks including, for example, Ethernet, the NMEA 2000 framework, GPS,
cellular, Wi-Fi, or other le networks. The network may also support other data sources,
including GPS, autopilot, engine data, compass, radar, etc. In this regard, numerous other
eral devices (including other marine electronic devices or sonar transducer lies)
may be included in the system 300.
The position sensor 345 may be configured to determine the t position and/or
location of the marine electronic device 305 (and/or the watercraft 100). For e, the
position sensor 345 may comprise a GPS, bottom contour, inertial navigation , such as
machined electromagnetic sensor (MEMS), a ring laser gyroscope, or other location detection
system. Alternatively or in addition to determining the location of the marine electronic device
305 or the watercraft 100, the position sensor 345 may also be configured to determine the
position and/or orientation of an object outside of the watercraft 100.
The display 340 (e.g. one or more screens) may be configured to present images and
may include or otherwise be in communication with a user ace 335 configured to receive
input from a user. The display 340 may be, for example, a tional 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 340 may present one or more sets of data (or
images generated from the one or more sets of data). Such data includes chart data, radar data,
sonar data, r data, location data, position data, ation data, sonar data, or any other
type of information relevant to the watercraft. Sonar data may be received from one or more
sonar transducer assemblies 362 or from sonar devices positioned at other locations, such as
remote from the watercraft. Additional data may be received from marine devices such as a
radar 356, a primary motor 358 or an associated sensor, a trolling motor 359 or an associated
sensor, an autopilot, a rudder 357 or an ated sensor, a position sensor 345, a direction
sensor 348, other sensors 352, a remote device 354, onboard memory 320 (e.g., stored chart data,
historical data, etc.), or other devices.
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 atively, depth information,
weather information, radar information, sonar information, or any other tion system inputs
may be applied to one another.
The user ace 335 may e, for example, a keyboard, keypad, function keys,
mouse, scrolling , input/output ports, touch screen, or any other mechanism by which a
user may interface with the system.
Although the display 340 of is shown as being directly connected to the at
least one processor 310 and within the marine onic device 305, the display 340 could
alternatively be remote from the at least one processor 310 and/or marine electronic device 305.
Likewise, in some embodiments, the position sensor 345 and/or user interface 335 could be
remote from the marine electronic device 305.
The marine onic device 305 may include one or more other sensors/devices 352,
such as configured to measure or sense s other conditions. The other sensors/devices 352
may include, for example, an air temperature , a water temperature , a current
sensor, a light sensor, a wind sensor, a speed sensor, or the like.
The sonar ucer assemblies 362 illustrated in may include one or more
sonar transducer elements 367, such as may be arranged to operate alone or in one or more
transducer arrays. In some embodiments, additional separate sonar ucer elements
(arranged to operate alone, in an array, or otherwise) may be included. As indicated , the
sonar transducer assemblies 362 may also include a sonar signal processor or other sor
(although not shown) configured to perform various sonar processing. In some embodiments,
the processor (e.g., at least one processor 310 in the marine electronic device 305, a controller (or
processor n) in the sonar transducer assemblies 362, or a remote controller — or
ations thereof) may be configured to filter sonar return data and/or selectively control
transducer element(s) 367. 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 s from the transducer element(s) 367.
The sonar transducer assemblies 362 may also include one or more other systems,
such as various sensor(s) 366. For example, the sonar transducer assembly 362 may include an
orientation , such as gyroscope or other orientation sensor (e.g., accelerometer, MEMS,
etc.) that can be configured to determine the relative orientation of the sonar transducer assembly
362 and/or the one or more sonar transducer element(s) 367 – such as with respect to a forward
direction of the watercraft. In some embodiments, additionally or alternatively, other types of
sensor(s) are contemplated, such as, for example, a water temperature sensor, a t sensor, a
light sensor, a wind sensor, a speed sensor, or the like.
The components presented in may be rearranged to alter the connections
between components. For example, in some embodiments, a marine device outside of the
marine electronic device 305, such as the radar 356, may be directly connected to the at least one
processor 310 rather than being connected to the communication interface 330. Additionally,
sensors and devices implemented within the marine electronic device 305 may be directly
connected to the communications interface in some embodiments rather than being directly
connected to the at least one processor 310.
Example Flowchart(s) and Operations
Some ments of the present invention provide methods, apparatus, and
computer program products related to the tation of information according to s
embodiments described herein. s examples of the operations performed in ance
with embodiments of the present ion will now be provided with reference to FIGs. 10-13.
FIGs. 10-13 present a flowchart with example method(s) of determination of a marine
environment area and corresponding navigation thereof. These methods may be performed by a
wide variety of ents, including, but not limited to, one or more processors, one or more
microprocessors, and one or more controllers. In some embodiments, a marine electronic device
305 ( may comprise one or more processors that perform the functions shown in FIGs.
-13. Further, these methods may be provided on a piece of software which runs on a central
server that is at a remote location away from the watercraft, and the remote server may
communicate with a sor or a similar component on the watercraft. Additionally, the
s could be ated into a software update that may be installed onto existing hardware,
or the methods may be integrated into the initial software or hardware provided in a radar unit,
watercraft, server, etc.
FIGs. 10-13 rate a art of an example method 400 for determination of a
marine environment area and corresponding navigation thereof, in accordance with some
embodiments discussed herein. The operations illustrated in and described with respect to FIGs.
-13 may, for example, by performed by, with the assistance of, , under the control of
one or more of the processor 310, memory 320, communication interface 330, user interface 335,
position sensor 345, direction sensor 348, other sensor 352, autopilot 350, transducer assembly
362, 362’, 362’’, display 340, radar 356, rudder 357, primary motor 358, trolling motor 359,
additional s 360, and/or external k 302/remote device 354.
At operation 402, the method comprises presentation of a chart, including a body of
water. At operation 404, the method comprises determining a condition parameter associated
with a desired marine environment. At operation 406, the method comprises determining a
portion of the body of water that is defined by the at least one condition parameter. At operation
408, the method comprises causing the presentation of the determined portion on the display of
the chart. At operation 410, the method comprises determining a traversal coverage
corresponding to a watercraft. At operation 412, the method comprises determining a route to
traverse the determined portion, such as based on the traversal coverage.
With reference to , at operation 414, the presentation of the chart may include
a representation of the watercraft at the current location.
With reference to , after determination of the portion at operation 406, the
method may also e determining that the determined portion is too small (or large), at
operation 416, and changing and/or adding a condition parameter(s) to adjust the size of the
determine n at operation 418 (such as via a suggestion).
With reference to , after causing presentation of the determined portion at
operation 408, the method may include, at operation 420, determining at least one transducer of
the watercraft and, at operation 422, ining a beam shape corresponding to the at least one
transducer. The method may continue, at operation 424, by ining a depth of the bottom
surface of the body of water at a current location of the watercraft and, at operation 426,
determining a sonar beam footprint of the sonar transducer (such as may be used in determining
the traversal coverage for ion 410).
FIGs. 10-13 illustrates a flowchart of a system, method, and computer program
product according to various example embodiments. It will be understood that each block of the
flowcharts, and combinations of blocks in the arts, may be ented by various
means, such as hardware and/or a computer program product comprising one or more computerreadable
s 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 m product(s)
which embody the ures described herein may be stored by, for example, the memory 320
and executed by, for example, the processor 310. As will be appreciated, any such computer
program product may be loaded onto a computer or other programmable apparatus (for e,
a marine electronic device 305) to produce a machine, such that the computer program product
including the instructions which e on the er or other programmable apparatus
s means for implementing the functions specified in the flowchart block(s). Further, the
er program product may se 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 305) to cause a series of operations to be performed on the er
or other programmable apparatus to produce a computer-implemented process such that the
ctions which execute on the computer or other programmable apparatus ent 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 ing ptions 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 cations 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 ons 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 bed 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.
Claims (20)
1. A marine data system comprising: a display; a processor; and a memory ing computer program code configured, when executed by the processor, cause, on the display, presentation of a chart including at least a portion of a body of water; e user input ting at least one condition parameter associated with a desired marine environment within the body of water; ine a n of the body of water that is defined by the at least one condition parameter; cause, on the display, presentation of an indication of the determined portion of the body of water on the chart, wherein the presentation of the indication of the determined portion includes highlighting a n of the body of water on the chart representing the determined portion; determine a traversal coverage corresponding to a raft; and determine a route, based on the determined traversal coverage, to traverse the determined portion such that an entirety of the determined portion is covered by the determined traversal coverage of the watercraft in an instance in which the watercraft traverses the determined route.
2. The marine data system of claim 1, wherein the traversal coverage is based on a sonar beam footprint of a sonar transducer of the watercraft, wherein the sonar beam footprint corresponds to a projection of a beam shape of one or more sonar beams of the sonar transducer at a determined depth, wherein the determined depth corresponds to the bottom surface of the body of water.
3. The marine data system of claim 1, wherein the computer program code is further configured, when executed by the processor, to cause, on the display, presentation of a representation of the determined traversal coverage on the chart relative to a current position of the raft.
4. The marine data system of claim 1, wherein the computer program code is further configured, when executed by the processor, to cause, on the y, presentation of a trail ting historical positions of the raft along the determined route, wherein the trail includes a representation of the determined traversal coverage so as to indicate which part of the determined portion has been covered by the determined route.
5. The marine data system of claim 1, n the determined traversal coverage is a selected width.
6. The marine data system of claim 1, wherein the determined traversal coverage is based on at least one of a width of the watercraft, a width corresponding to a fishing cast distance, or a width corresponding to a towed fishing line.
7. The marine data system of claim 1, wherein the determined route is configured to ze the number of turns by the watercraft.
8. The marine data system of claim 1, wherein the determined route includes maneuvering outside of the determined portion so as to minimize turns by the watercraft.
9. The marine data system of claim 1, wherein the determined route does not include turns that are greater than 75º.
10. The marine data system of claim 1, wherein the computer program code is r configured, when executed by the processor, to cause an lot to cause the watercraft to traverse the ined route.
11. The marine data system of claim 1, wherein data corresponding to the at least one condition parameter is gathered from at least one of a global positioning system (GPS), satellite data, navigation data, prior track data, or server data.
12. The marine data system of claim 1, wherein the at least one condition ter includes a range of estimated or determined water temperatures within a range of water depths.
13. The marine data system of claim 1, wherein the computer program code is further configured, when executed by the processor, to: calculate a time of traverse, wherein the time of traverse is based on a speed of the watercraft and the determined route to traverse the determined portion; and cause, on the display, an indication of the time of traverse.
14. The marine data system of claim 1, n the route is further determined by a determined desired speed of traversal of the watercraft.
15. The marine data system of claim 1, wherein the ined portion of the body of water includes a ity of distinct portions of the body of water, wherein the plurality of distinct portions of the body of water include a first distinct portion of the body of water and a second distinct portion of the body of water, wherein the first distinct portion of the body of water is separated from the second distinct portion of the body of water by a third portion of the body of water that does not y the at least one condition parameter, and wherein the determined route traverses between the first distinct portion of the body of water and the second distinct n of the body of water so as to traverse the entirety of the determined plurality of the distinct portions of the body of water.
16. The marine data system of claim 15, wherein the determined route, when ed by lot, is determined so as to cause the raft to traverse the first distinct portion of the body of water and the second distinct portion of the body of water at a first speed, and the third n of the body of water at a second speed, wherein the first speed is different than the second speed.
17. The marine data system of claim 1, wherein the computer program code is further configured, when executed by the processor, to cause, on the display, an indication of the determined route.
18. The marine data system of claim 1, wherein the computer program code is further configured, when executed by the processor, to: determine an adjusted portion of the body of water that is defined by, in comparison to the determined portion, at least one of a different range of the at least one condition parameter or the at least one condition parameter and an additional parameter; and cause, on the display, presentation of an indication of the adjusted n.
19. A method, the method comprising: causing, on a display, a presentation of a chart including at least a portion of a body of water; receiving user input indicating at least one condition parameter associated with a desired marine environment within the body of water; determining, via a sor, a portion of the body of water that is defined by the at least one ion parameter; causing, on the display, tation of an indication of the determined portion on the chart, wherein the presentation of the indication of the determined portion includes highlighting a portion of the body of water representing the determined portion; determining, via the processor, a traversal coverage corresponding to a watercraft; and determining, via the processor, a route based on the determined traversal coverage, to traverse the determined portion such that an entirety of the determined n is covered by the ined traversal coverage of the watercraft in an instance in which the watercraft traverses the determined route.
20. A non-transitory computer-readable medium having stored thereon a plurality of computer-executable instructions, which, when executed by a processor, cause the processor to: cause, on a display, presentation of a chart including at least a portion of a body of water; determine at least one condition parameter associated with a desired marine nment within the body of water; determine, via a processor, a portion of the body of water that is defined by the at least one condition parameter; cause, on the display, presentation of an indication of the determined n on the chart, wherein the presentation of the indication of the determined portion includes ghting a portion of the body of water on the chart representing the determined portion; determine, via a processor, a traversal coverage corresponding to a watercraft; and determine a route, based on the determined sal ge, to traverse the determined portion such that an entirety of the determined portion is covered by the determined traversal ge of the watercraft in an instance in which the watercraft ses the determined route.
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US17/218,492 | 2021-03-31 |
Publications (1)
Publication Number | Publication Date |
---|---|
NZ786470A true NZ786470A (en) | 2022-03-25 |
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