Kevin, a rangefinder is very costly and heavy for smaller aircraft. I'm trying to make this software-based that can interface with most cameras and gimbals. All you will need, in theory, is a computer, camera, video stream, and gimbal.
For what I need this app for, it is great. Simple to use, different formats for timestamps, and ability to highlight the moment from weather to position of latitude and longitude. It also has extra features with minor ads. Also, the fact that there is a small map to help isolate the area you are in. There is a pro version, which I have no need for such. This is great for security detail work pictures. Great Great great... Thank you!
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If you don't specify the camera position when the style is loaded, default values will be used. If the style being loaded has center, bearing, pitch, and zoom properties defined, the position will be determined by those values. If these properties are not defined in the style JSON, the map will be centered on the coordinates 0,0 with a bearing and pitch of 0 at zoom level 0.
campos(g,'auto') sets the camera position to an automatic mode, enabling the geographic globe to determine the latitude and longitude of the camera based on the plotted data. The mode defaults to automatic when you create a geographic globe. If you change the camera position using your mouse, then the mode switches to automatic. To control the mode for the height of the camera, use the camheight function instead.
campos(g,'manual') sets the camera position to a manual mode, specifying that the geographic globe preserve the latitude and longitude of the camera when the plotted data changes. If you change the camera position using the campos function, then the mode switches to manual.
[latOut,lonOut,heightOut] = campos(___) sets the position or mode and then returns the latitude, longitude, and height of the camera. You can return the camera position using any of the previous syntaxes.
The overlaps between strips was 65%. Unfortunately until now from 8 flights we have only one complete mosaic while in the rest we have only partly mosaics. The flights was done with DJI Matrice 600 and Flir A655sc thermal camera. Before we place images in the pix4D we gave each image from the Flir the relevant geodata from the drone.
Hi Hadar, Accurate geolocation and orientation works when you have orienation data and also the geolocation and orienation values should be accurate (like RTK). But from our exprience we have seen thsi method also working for normal cameras. When you have nadir and oblique imagery both, this option works the best. Also, for homogeneous areas, it would work better than standard. Standard calibration is used when you have a lot of heterogeneity in terms of texture, object height (like buildings etc). Alternative calibration is used for homogeneous areas but is based on the assumption that the images are nadir and the area is flat. If the angle >35% (sue to oblque camera angle, slope) Pix4D fails to calibrate such images with alternative calibration. Thus in these cases, accurate geolocation and orientation works better
Updated February 2009: added mention of , , and .Introduced with KML 2.2, provides an additional way to specify the observer's viewpoint and associated view parameters. is similar to , since both elements define the placement and orientation of a virtual camera that is viewing the Earth. The difference is that LookAt specifies the view in terms of the point of interest that is being viewed. Camera, in contrast, specifies the view in terms of the viewer's position and orientation.
An automated driving system can contain sensors located anywhere on or in the vehicle. The location of each sensor contains an origin of its coordinate system. A camera is one type of sensor used often in an automated driving system. Points represented in a camera coordinate system are described with the origin located at the optical center of the camera.
The projected components. These have been available since AR.js 3.3.1, use largely the same internal implementation as the classic components, and were the first to offer projection of latitude/longitude into Spherical Mercator, discussed below.
The classic components, available before AR.js 3.3.1. These are similar to the projected components but do not offer the facility to convert between latitude/longitude and the projected coordinates used for augmented reality, which can cause problems for more specialist uses such as showing roads and paths in augmented reality.
Each variant above includes two components, a camera component which enables the location-based AR, and an entity-place component which enables setting components' latitude and longitude. The exact component names for each variant are shown below.
Spherical Mercator is the same projection used by Google Maps and projects the earth onto a flat surface. It works reasonably at most latitudes but is highly distorted near the poles. Latitude and longitude is projected into Spherical Mercator eastings and northings, which are approximately (but not exactly) equivalent to metres.
The key method is the latLonToWorld(lat, lon) method of the gps-new-camera and gps-projected-camera components. This converts latitude and longitude directly to world coordinates, performing the projection as the first step and then calculating the world coordinates from the projected coordinates. It will return a 2-member array containing the x and z world coordinates, allowing the developer to calculate or specify the y coordinate (altitude) independently.
gps-projected-camera provides similar functionality but via a different method and with some implementation differences. In gps-projected-camera, unlike gps-new-camera, the original GPS position is set as the world origin.
setProjection(proj) : allows the projection to be defined. By default Spherical Mercator is used. The projection object must provide a project() method which takes longitude and latitude as parameters and returns a 2-member array of projected coordinates (easting, northing).
lonLatToWorldCoords(lon, lat) : projects a given longitude and latitude into world coordinates using the current projection. The sign of the northing is reversed to align it with the OpenGL coordinate system.
I have the same issue with my Rainbow Astro RST-135. I end up with a wild longitude number such as 488E while I am 110W. I cannot continue when that happens. And it might initially pick up the correct numbers but somewhere along the line it gets changed. I hope they fix this because I basically have to start over when that happens as GoTos no longer work. Also "Sync to mount" does nothing. I press the button and it says completed, but no change is made.
I am using a Jackery 240 Power Station to power things inside. If I power the mount directly from this, it gets 13.3v. Going through the ASIAIR for power it gets 12.8v. Outside I might use a Pyramid Power Supply which usually gives me 13.8v as I recall.
Right now I just have the mount attached to the ASIAIR with the supplied USB and power cables. No camera or other device is attached. I am not using any hub. I am able to control the mount with SkySafari and Luminos apps on my iPad Mini through WiFi. The last time I was out and I got the mount and ASIAIR to sync, I was able to take a couple of hours worth of images. The plate solving was fantastic. The ASIAIR is a great product once it is working properly. I will take a look at ASCOM and load the latest firmware. I think Stellarium can now connect via ASCOM without any secondary software.
i need to display three.js sphere at specific latitude longitude. and as i rotate my device it should be displayed in my device by my application camera. all things will be dynamic. do i need to use three.js DeviceOrientationControls ? if yes then how can I ?
here is my code but it displays nothing.
i can run simple cube demo in my application but not able to display three.js object on latitude and longitude.
please help me. is there anyone expert with three.js then please help me.
The GPS function is the newest feature to be added to some of the EOS and PowerShot cameras. While there are certain models that require an external receiver, there are also other models with a built-in antenna that can obtain GPS information via satellite all on the camera itself.
Data such as the latitude, longitude, elevation, and Coordinated Universal Time (UTC), is recorded as EXIF metadata, which is then appended to the image. Using dedicated software, you can check the positions with ease after shooting, and also trace the path that you took with your camera on a map. You can utilise these features to indicate the locations of your shots with pinpoint accuracy even in places where it is hard to identify the location by simply looking at the photo, such as in a snowy field or on a coastline. The location data can be used as a guide if you were to ever revisit the shooting location. Another plus is that it makes it easier for you to add a detailed explanation to your shots when applying for photography contests and the like.
This is the GPS information as displayed on the EOS 6D. The camera receives information on latitude, longitude, elevation and so on from GPS satellites, which is then recorded inside the camera and appended to the image data.
The image data with the recorded GPS information is shown. Detailed information such as latitude and longitude is embedded in the data space, allowing you to check the detailed positional information.
The ideal would be to create a geolocation module like in darktable but simpler. A world map, the photos in the movie roll and drag and drop to place its image on the map. Without the images necessarily remaining on this map as in darkktable. Just to automatically enter the latitude and longitude which avoids going through google maps.
GPS Camera can help you to add the address, location coordinates direction, altitude, current date & time & note in the picture.There is a coordinate converter to switch between any of the common coordinate systems including Lat/Long, UTM, and MGRS so it can work with any physical map.
You can also set the camera function , such as flash on / off, night, zoom, the resolution of the camera ...
After you finish your shot, you can save it or share it with your friends directly in the action press the icon. You can also view photos you took using his picture browser.
* Coordinate types:
- Dec Degs (DD.dddddd)
- Dec Degs Micro (DD.dddddd "N, S, E, W")
- Dec Mins (DDMM.mmmm)
- Deg Min Secs (DDMM'SS.sss")
- Dec Mins Secs (DDMMSS.sss")
- UTM (Universal Transverse Mercator)
- MGRS (Military Grid Reference System) e24fc04721