The SAT-format feature handles import and export precise geometric boundary representation (BREP) data, also known as ACIS solids, for trimmed surfaces, solids models and assemblies as 3ds Max 'Body Objects.” SAT-format objects can come from Autodesk programs such as Revit and Inventor, as well as third-party software like Rhino and Catia.
SatFile Filter was designed to be a powerful easy to use free utility for renaming and sorting files that downloaded form satellite by programs like SkyNet and others. Defines the SatFile class for doing ACIS save and restore to stream files in text format. Constructor: public: SatFile::SatFile (FILE. // filename); C constructor, creating a SatFile using the specified parameters. Destructor: public: virtual SatFile::SatFile ; C destructor, deleting a SatFile. Landsat 5 TM Collection 1 Tier 1 DN values, representing scaled, calibrated at-sensor radiance.Landsat scenes with the highest available data quality are placed into Tier 1 and are considered suitable for time-series processing analysis. Tier 1 includes Level-1 Precision Terrain (L1TP) processed data that have well-characterized radiometry and are inter-calibrated.
Also included: Join Bodies and Body Cutter, which are commands for combining and subtracting Body Objects using Boolean operations; the ability to convert native 3ds Max objects to Body Objects; a utility for setting properties for multiple Body Objects at the same time; and Body Object-specific snap options. Airbag tool 24.05.08 keygen.
When you import an SAT file, the resulting objects are Body Objects, and you can adjust their settings on the Modify panel using the rollouts described in this section. You can also use the Body Objects tools on the Create panel to work with imported Body Objects and convert 3ds Max primitives to Body Object format.
In addition to using the controls described in this section, you can apply a number of different 3ds Max modifiers to Body Objects, adjust the modifier settings to change their shapes or mapping, and then export the modified objects as ACIS solids without losing any data. The supported modifiers are listed in Editable Body Object Rollout.
Procedures
To use modifiers with Body Objects:
One of the most useful workflows with the SAT feature set is to import solid geometry, deform it with 3ds Max modifiers, and then export an SAT file, still in the ACIS solids format.
![Satfile Satfile](https://i.ytimg.com/vi/vb1smzFp2Co/maxresdefault.jpg)
- Export your geometry in SAT format from a solid-modeling program such as Autodesk Inventor or Revit. Alternatively, you can import Inventor IAM and IPT files directly as Body Objects Body Objects
- Import the SAT, IAM, or IPT file into 3ds Max. For details on the import parameters, see SAT Import Dialog or Importing Autodesk Inventor Files. TipFor optimal performance with large files (over 100MB), use the 64-bit version of 3ds Max with a large-memory system (8GB or more) and set the display to a single viewport before importing.For an SAT file, on the Import dialog, set Viewport Body Mesh Quality to Coarse.For an IAM or IPT file, import as Body Objects and then choose the Coarse setting on the Viewport Display Settings rollout after importing.The result is one or more Body Objects, which is the format solid geometry uses inside 3ds Max.
- Select each Body Object you plan to deform, and on the Modify panel set its Viewport Display Settings rollout Max Edge Len. % value to 2.0 or 3.0. TipYou can adjust viewport display settings for multiple objects simultaneously by selecting them and using the Body Utility tool.This setting provides for enough polygons for deforming planar faces.
- Apply a Mesh Select modifier to a Body Object, and then apply a deforming modifier such as Bend or Twist. The Mesh Select modifier converts the Body Object temporarily to mesh format, so it can deform more readily.
- Adjust the deforming modifier settings to obtain the desired results. If you like, apply other deforming modifiers and adjust them as well. For a list of supported modifiers, see Modifiers and Body Objects.
- Optionally, use the additional SAT tools described in this section to modify the Body Object. For example, you can convert native 3ds Max primitives to Body Objects and combine them with your geometry, optionally using Boolean operations such as Union, Intersect, and Subtract.
- When you’ve achieved the desired results, delete or turn off the Mesh Select modifier, NoteThere might be a delay after disabling Mesh Select, while the software applies the modifier effects directly to the solid geometry.
- You can now use the deformed object for rendering, or export it to a solid-modeling program as an SAT file.
To render Body Objects:
- Import an SAT or Inventor file as Body Objects.
- Group the different Body Objects in the file according to material property using layers, named selection sets, groups, or Containers.
- Inspect it visually for completeness. If there are holes in the surface, they're probably indicative of faces that need to be flipped.
- To correct for any holes, select the object, go to the Modify panel, and on the Editable Body Object rollout, click Face Flip. This opens the Face Flipping/Visibility rollout.
- On the Face Flipping/Visibility rollout, click Flip Faces Mode and then go around the model and click where the holes are. This reverses those faces so they're facing in the correct direction. When finished, click Face Flip again to close the rollout.
- When you render the object, the software creates a mesh whose resolution depends on the Rendering Approximation rollout settings. Use these settings to adjust how the object renders, as follows:
- Start with the Production Render Mesh Quality Preset, which is the default setting, and render. If the rendering is satisfactory and completes in a reasonable amount of time, you're done.
- If the rendering takes too long, try the Draft or Good preset.
- If, on the other hand, further improvement in the rendering quality is necessary, adjust the settings. For example, try reducing the Face Approx Angle to 20, and the Chord setting to 0.25. Also try setting low values for Edge Chord and Max Edge (set the latter to about 20).
- If edges render where they shouldn't, turn on Weld And Smooth Mesh.
- If the render-mesh quality is satisfactory but it takes a long time to render, and you want to try rendering from different angles or with different lighting, turn on Save Render Mesh. This saves time by precalculating and caching the render mesh.
- Render the model, make further adjustments as necessary, and re-render.
- If you want to render an animation, you’ll get faster results by turning on Render Approximation rollout Use Viewport Mesh, and then adjusting the Viewport Display Settings rollout parameters accordingly.
Topics in this section
- Body Objects CategoryAvailable on the Create panel drop-down list of object types is the Body Objects entry. When you choose this item, the Object Type rollout contains four buttons for different features of the SAT plug-in, described in this topic.
- Combining Body ObjectsThis section contains rollouts concerned with combining Body Objects with Join Bodies and Body Cutter.
- Import/Export/SnapsThis section covers dialogs for importing, exporting, and snapping to Body Objects.
Sat File Cad
Autocad Sat File
ee.ImageCollection('LANDSAT/LT05/C01/T1')
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Description
Landsat 5 TM Collection 1 Tier 1 DN values, representing scaled, calibrated at-sensor radiance.
Landsat scenes with the highest available data qualityare placed into Tier 1 and are considered suitable for time-series processinganalysis. Tier 1 includes Level-1 Precision Terrain (L1TP) processed datathat have well-characterized radiometry and are inter-calibrated across thedifferent Landsat sensors. The georegistration of Tier 1 scenes will beconsistent and within prescribed tolerances [<=12 m root mean square error(RMSE)]. All Tier 1 Landsat data can be considered consistent andinter-calibrated (regardless of sensor) across the full collection. See more informationin the USGS docs.
For more information, see USGS Landsat 5 Page
Sat File 3d
![File File](https://i.ytimg.com/vi/zzewa6yqPsk/maxresdefault.jpg)
Bands
BandsName | Pixel Size | Wavelength | Description | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
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B1 | 30 meters | 0.45 - 0.52 µm | Blue | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B2 | 30 meters | 0.52 - 0.60 µm | Green | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B3 | 30 meters | 0.63 - 0.69 µm | Red | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B4 | 30 meters | 0.76 - 0.90 µm | Near infrared | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B5 | 30 meters | 1.55 - 1.75 µm | Shortwave infrared 1 | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B6 | 30 meters | 10.40 - 12.50 µm | Thermal Infrared 1. Resampled from 60m to 30m. | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
B7 | 30 meters | 2.08 - 2.35 µm | Shortwave infrared 2 | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
BQA | Landsat Collection 1 QA Bitmask (See Landsat QA page) | ||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||||
Bitmask for BQA
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Image Properties
Image PropertiesName | Type | Description |
---|---|---|
CLOUD_COVER | DOUBLE | Percentage cloud cover, -1 = not calculated. |
CLOUD_COVER_LAND | DOUBLE | Percentage cloud cover over land, -1 = not calculated. |
COLLECTION_CATEGORY | STRING | Tier of scene. (T1 or T2) |
COLLECTION_NUMBER | DOUBLE | Number of collection. |
CORRECTION_BIAS_BAND_1 | STRING | Internal calibration bias method for band 1. |
CORRECTION_BIAS_BAND_2 | STRING | Internal calibration bias method for band 2. |
CORRECTION_BIAS_BAND_3 | STRING | Decrypt p file matlab free. Internal calibration bias method for band 3. |
CORRECTION_BIAS_BAND_4 | STRING | Internal calibration bias method for band 4. |
CORRECTION_BIAS_BAND_5 | STRING | Internal calibration bias method for band 5. Megastat for mac. |
CORRECTION_BIAS_BAND_6 | STRING | Internal calibration bias method for band 6. |
CORRECTION_BIAS_BAND_7 | STRING | Internal calibration bias method for band 7. |
CORRECTION_GAIN_BAND_1 | STRING | Internal calibration gain method for band 1. |
CORRECTION_GAIN_BAND_2 | STRING | Internal calibration gain method for band 2. |
CORRECTION_GAIN_BAND_3 | STRING | Internal calibration gain method for band 3. |
CORRECTION_GAIN_BAND_4 | STRING | Internal calibration gain method for band 4. |
CORRECTION_GAIN_BAND_5 | STRING | Internal calibration gain method for band 5. |
CORRECTION_GAIN_BAND_6 | STRING | Internal calibration gain method for band 6. |
CORRECTION_GAIN_BAND_7 | STRING | Internal calibration gain method for band 7. |
CPF_NAME | STRING | Calibration parameter file name. |
DATA_CATEGORY | STRING | Current data category assigned to the data. Possible values: ('NOMINAL', 'VALIDATION', 'EXCHANGE', 'TEST', 'ENGINEERING') |
DATA_TYPE | STRING | Data type identifier. (L1T or L1G) |
DATA_TYPE_L0RP | STRING | Data type identifier string used to create the L0RP product. |
DATE_ACQUIRED | STRING | Image acquisition date. 'YYYY-MM-DD' |
DATUM | STRING | Datum used in image creation. |
EARTH_SUN_DISTANCE | DOUBLE | Earth sun distance in astronomical units (AU). |
ELEVATION_SOURCE | STRING | Elevation model source used for standard terrain corrected (L1T) products. |
ELLIPSOID | STRING | Ellipsoid used in image creation. |
EPHEMERIS_TYPE | STRING | Ephemeris data type used to perform geometric correction. (Definitive or Predictive) |
FILE_DATE | DOUBLE | File date in milliseconds since epoch. |
GEOMETRIC_RMSE_MODEL | DOUBLE | Combined Root Mean Square Error (RMSE) of the geometric residuals(metres) in both across-track and along-track directionsmeasured on the GCPs used in geometric precision correction.Not present in L1G products. |
GEOMETRIC_RMSE_MODEL_X | DOUBLE | RMSE of the X direction geometric residuals (in metres) measuredon the GCPs used in geometric precision correction. Not present inL1G products. |
GEOMETRIC_RMSE_MODEL_Y | DOUBLE | RMSE of the Y direction geometric residuals (in metres) measuredon the GCPs used in geometric precision correction. Not present inL1G products. |
GEOMETRIC_RMSE_VERIFY | DOUBLE | RMSE of the geometric residuals (pixels) in both line and sampledirections measured on the terrain-corrected product independentlyusing GLS2000. |
GEOMETRIC_RMSE_VERIFY_QUAD_LL | DOUBLE | RMSE of the geometric residuals (pixels) of the lower-left quadrantmeasured on the terrain-corrected product independently using GLS2000. |
GEOMETRIC_RMSE_VERIFY_QUAD_LR | DOUBLE | RMSE of the geometric residuals (pixels) of the lower-right quadrantmeasured on the terrain-corrected product independently using GLS2000. |
GEOMETRIC_RMSE_VERIFY_QUAD_UL | DOUBLE | RMSE of the geometric residuals (pixels) of the upper-left quadrantmeasured on the terrain-corrected product independently using GLS2000. |
GEOMETRIC_RMSE_VERIFY_QUAD_UR | DOUBLE | RMSE of the geometric residuals (pixels) of the upper-right quadrantmeasured on the terrain-corrected product independently using GLS2000. |
GRID_CELL_SIZE_REFLECTIVE | DOUBLE | Grid cell size used in creating the image for the reflective band. |
GRID_CELL_SIZE_THERMAL | DOUBLE | Grid cell size used in creating the image for the thermal band. |
GROUND_CONTROL_POINTS_MODEL | DOUBLE | The number of ground control points used. Not used in L1GT products.Values: 0 - 999 (0 is used for L1T products that have usedMulti-scene refinement). |
GROUND_CONTROL_POINTS_VERIFY | DOUBLE | The number of ground control points used in the verification ofthe terrain corrected product. Values: -1 to 1615 (-1 = not available) |
GROUND_CONTROL_POINTS_VERSION | DOUBLE | The number of ground control points used in the verification ofthe terrain corrected product. Values: -1 to 1615 (-1 = not available) |
IMAGE_QUALITY | DOUBLE | Image quality, 0 = worst, 9 = best, -1 = quality not calculated |
K1_CONSTANT_BAND_6 | DOUBLE | Calibration constant K1 for Band 6 radiance to temperature conversion. |
K2_CONSTANT_BAND_6 | DOUBLE | Calibration constant K2 for Band 6 radiance to temperature conversion. |
LANDSAT_PRODUCT_ID | STRING | The naming convention of each Landsat Collection 1 Level-1 image basedon acquisition parameters and processing parameters. Format: LXSS_LLLL_PPPRRR_YYYYMMDD_yyyymmdd_CC_TX
|
LANDSAT_SCENE_ID | STRING | The Pre-Collection naming convention of each image is based on acquisitionparameters. This was the naming convention used prior to Collection 1. Format: LXSPPPRRRYYYYDDDGSIVV
|
MAP_PROJECTION | STRING | Projection used to represent the 3-dimensional surface of the earth for the Level-1 product. |
MAP_PROJECTION_L0RA | STRING | L0RA map projection selectively applied to HDTs based on geographic location. Used for processed archive data. |
ORIENTATION | STRING | Orientation used in creating the image. Values: NOMINAL = Nominal Path, NORTH_UP = North Up, TRUE_NORTH = True North, USER = User |
PROCESSING_SOFTWARE_VERSION | STRING | Name and version of the processing software used to generate the L1 product. |
RADIANCE_ADD_BAND_1 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 1. |
RADIANCE_ADD_BAND_2 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 2. |
RADIANCE_ADD_BAND_3 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 3. |
RADIANCE_ADD_BAND_4 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 4. |
RADIANCE_ADD_BAND_5 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 5. |
RADIANCE_ADD_BAND_6 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 6. |
RADIANCE_ADD_BAND_7 | DOUBLE | Additive rescaling factor used to convert calibrated DN to radiance for Band 7. |
RADIANCE_MULT_BAND_1 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 1 DN to radiance. |
RADIANCE_MULT_BAND_2 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 2 DN to radiance. |
RADIANCE_MULT_BAND_3 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 3 DN to radiance. |
RADIANCE_MULT_BAND_4 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 4 DN to radiance. How to use little snitch to block adobe cc free. |
RADIANCE_MULT_BAND_5 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 5 DN to radiance. |
RADIANCE_MULT_BAND_6 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 6 DN to radiance. |
RADIANCE_MULT_BAND_7 | DOUBLE | Multiplicative rescaling factor used to convert calibrated Band 7 DN to radiance. |
REFLECTANCE_ADD_BAND_1 | DOUBLE | Additive rescaling factor used to convert calibrated Band 1 DN to reflectance. |
REFLECTANCE_ADD_BAND_2 | DOUBLE | Additive rescaling factor used to convert calibrated Band 2 DN to reflectance. |
REFLECTANCE_ADD_BAND_3 | DOUBLE | Additive rescaling factor used to convert calibrated Band 3 DN to reflectance. |
REFLECTANCE_ADD_BAND_4 | DOUBLE | Additive rescaling factor used to convert calibrated Band 4 DN to reflectance. |
REFLECTANCE_ADD_BAND_5 | DOUBLE | Additive rescaling factor used to convert calibrated Band 5 DN to reflectance. |
REFLECTANCE_ADD_BAND_7 | DOUBLE | Multiplicative factor used to convert calibrated Band 7 DN to reflectance. |
REFLECTANCE_MULT_BAND_1 | DOUBLE | Multiplicative factor used to convert calibrated Band 1 DN to reflectance. |
REFLECTANCE_MULT_BAND_2 | DOUBLE | Multiplicative factor used to convert calibrated Band 2 DN to reflectance. |
REFLECTANCE_MULT_BAND_3 | DOUBLE | Multiplicative factor used to convert calibrated Band 3 DN to reflectance. |
REFLECTANCE_MULT_BAND_4 | DOUBLE | Multiplicative factor used to convert calibrated Band 4 DN to reflectance. |
REFLECTANCE_MULT_BAND_5 | DOUBLE | Multiplicative factor used to convert calibrated Band 5 DN to reflectance. |
REFLECTANCE_MULT_BAND_7 | DOUBLE | Multiplicative factor used to convert calibrated Band 7 DN to reflectance. |
REFLECTIVE_LINES | DOUBLE | Number of product lines for the reflective bands. |
REFLECTIVE_SAMPLES | DOUBLE | Number of product samples for the reflective bands. |
REQUEST_ID | STRING | Request id, nnnyymmdd0000_0000
|
RESAMPLING_OPTION | STRING | Resampling option used in creating the image. |
SATURATION_BAND_1 | STRING | Flag indicating saturated pixels for band 1 ('Y'/'N') |
SATURATION_BAND_2 | STRING | Flag indicating saturated pixels for band 2 ('Y'/'N') |
SATURATION_BAND_3 | STRING | Flag indicating saturated pixels for band 3 ('Y'/'N') |
SATURATION_BAND_4 | STRING | Flag indicating saturated pixels for band 4 ('Y'/'N') |
SATURATION_BAND_5 | STRING | Flag indicating saturated pixels for band 5 ('Y'/'N') |
SATURATION_BAND_6 | STRING | Flag indicating saturated pixels for band 6 ('Y'/'N') |
SATURATION_BAND_7 | STRING | Flag indicating saturated pixels for band 7 ('Y'/'N') |
SCENE_CENTER_TIME | STRING | Scene center time of acquired image. HH:MM:SS.SSSSSSSZ
|
SENSOR_ID | STRING | Sensor used to capture data. |
SENSOR_MODE | STRING | Operational mode. Scan Angle Monitor (SAM) or BUMPER. |
SPACECRAFT_ID | STRING | Spacecraft identification. |
STATION_ID | STRING | Ground Station/Organisation that received the data. |
SUN_AZIMUTH | DOUBLE | Sun azimuth angle in degrees for the image center location at the image centre acquisition time. |
SUN_ELEVATION | DOUBLE | Sun elevation angle in degrees for the image center location at the image centre acquisition time. |
THERMAL_LINES | DOUBLE | Number of product lines for the thermal band. |
THERMAL_SAMPLES | DOUBLE | Number of product samples for the thermal band. |
UTM_ZONE | DOUBLE | UTM zone number used in product map projection. |
WRS_PATH | DOUBLE | The WRS orbital path number (001 - 251). |
WRS_ROW | DOUBLE | Landsat satellite WRS row (001-248). |