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pg-rad/docs/quickstart.md
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## Installation
See the [installation guide](installation.md).
## Test your installation
First, see if PG-RAD is available on your system by typing
```
pgrad --help
```
You should get output along the lines of
```
usage: pg-rad [-h] ...
Primary Gamma RADiation landscape tool
...
```
If you get something like `pgrad: command not found`, please consult the [installation guide](installation.md).
You can run a quick test scenario as follows:
```
pgrad --test
```
This should produce a plot of a scenario containing a single point source and a path.
## Running PG-RAD
In order to use the CLI for your own simulations, you need to provide a *config file*. To run with your config, run
```
pgrad --config path/to/my_config.yml
```
where `path/to/my_config.yml` points to your config file.
## Example configs
The easiest way is to take one of these example configs, and adjust them as needed. Alternatively, there is a detailed guide on how to write your own config file [here](config-spec.md).
=== "Example 1"
The position can be defined relative to the path. `along_path` means at what distance traveled along the path the source is found. If the path is 200 meters long and `along_path` is `100` then the source is halfway along the path. `dist_from_path` is the distance in meters from the path. `side` is the side of the path the source is located. This is relative to the direction the path is traveled.
``` yaml
name: Example 1
speed: 13.89
acquisition_time: 1
path:
file: path/to/exp_coords.csv
east_col_name: East
north_col_name: North
sources:
source1:
activity_MBq: 1000
isotope: CS137
position:
along_path: 100
dist_from_path: 50
side: left
detector:
name: dummy
is_isotropic: True
```
=== "Example 2"
The position can also just be defined with (x,y,z) coordinates.
``` yaml
name: Example 2
speed: 13.89
acquisition_time: 1
path:
file: path/to/exp_coords.csv
east_col_name: East
north_col_name: North
sources:
source1:
activity_MBq: 1000
isotope: CS137
position: [104.3, 32.5, 0]
source2:
activity_MBq: 100
isotope: CS137
position: [0, 0, 0]
detector:
name: dummy
is_isotropic: True
```
=== "Example 3"
This is an example of a procedural path with random apportionment of total length and random angles being assigned to turns. The parameter `alpha` is optional, and is related to randomness. A higher value leads to more uniform apportionment of lengths and a lower value to more random apportionment. More information about `alpha` can be found [here](pg-rad-config-spec.md).
``` yaml
name: Example 3
speed: 8.33
acquisition_time: 1
path:
length: 1000
segments:
- straight
- turn_left
- straight
alpha: 100
sources:
source1:
activity_MBq: 1000
isotope: CS137
position: [0, 0, 0]
detector:
name: dummy
is_isotropic: True
```
=== "Example 4"
This is an example of a procedural path that is partially specified. Note that turn_left now is a key for the corresponding angle of 45 degrees. The length is still divided randomly
``` yaml
name: Example 4
speed: 8.33
acquisition_time: 1
path:
length: 1000
segments:
- straight
- turn_left: 45
- straight
sources:
source1:
activity_MBq: 1000
isotope: CS137
position: [0, 0, 0]
detector:
name: dummy
is_isotropic: True
```
=== "Example 5"
This is an example of a procedural path that is fully specified. See how length is now a list matching the length of the segments.
``` yaml
name: Example 5
speed: 8.33
acquisition_time: 1
path:
length:
- 400
- 200
- 400
segments:
- straight
- turn_left: 45
- straight
sources:
source1:
activity_MBq: 1000
isotope: CS137
position: [0, 0, 0]
detector:
name: dummy
is_isotropic: True
```
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