No version for distro humble. Known supported distros are highlighted in the buttons above.
No version for distro iron. Known supported distros are highlighted in the buttons above.
No version for distro jazzy. Known supported distros are highlighted in the buttons above.
No version for distro rolling. Known supported distros are highlighted in the buttons above.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.3.1 |
Last Updated | 2018-08-06 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.3.1 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Examples:
The following can be run from the directory containing test_sbpl,
which we assume is a build directory in the root of this project.
$ ./test_sbpl ../env_examples/nav3d/env1.cfg
Environment: xytheta; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=16
solution size=0
Solution is found
$ ./test_sbpl --env=2d ../env_examples/nav2d/env1.cfg #2d is needed here in order to use 2d config
Environment: 2d; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=22
Solution is found
$ ./test_sbpl --env=robarm --search-dir=forward --planner=rstar ../env_examples/robarm/env1_6d.cfg
Environment: robarm; Planner: rstar; Search direction: forward
Initializing RSTARPlanner...
start planning...
done planning
size of solution=44
Solution is found
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
No version for distro ardent. Known supported distros are highlighted in the buttons above.
No version for distro bouncy. Known supported distros are highlighted in the buttons above.
No version for distro crystal. Known supported distros are highlighted in the buttons above.
No version for distro eloquent. Known supported distros are highlighted in the buttons above.
No version for distro dashing. Known supported distros are highlighted in the buttons above.
No version for distro galactic. Known supported distros are highlighted in the buttons above.
No version for distro foxy. Known supported distros are highlighted in the buttons above.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.3.1 |
Last Updated | 2018-08-06 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.3.1 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Examples:
The following can be run from the directory containing test_sbpl,
which we assume is a build directory in the root of this project.
$ ./test_sbpl ../env_examples/nav3d/env1.cfg
Environment: xytheta; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=16
solution size=0
Solution is found
$ ./test_sbpl --env=2d ../env_examples/nav2d/env1.cfg #2d is needed here in order to use 2d config
Environment: 2d; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=22
Solution is found
$ ./test_sbpl --env=robarm --search-dir=forward --planner=rstar ../env_examples/robarm/env1_6d.cfg
Environment: robarm; Planner: rstar; Search direction: forward
Initializing RSTARPlanner...
start planning...
done planning
size of solution=44
Solution is found
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.2.0 |
Last Updated | 2014-08-08 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.2.0 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.2.0 |
Last Updated | 2014-08-08 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.2.0 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.1.4 |
Last Updated | 2013-01-07 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.1.4 |
README
Compilation:
a) Under windows, SBPL can be compiled using a project inside sbpl\win32_build\test_vs2007.
This supports Visual Studio 7.0. Other projects in wind32_build directory may be
outdated and may therefore require you to add new .cpp files to the project.
b) Under unix/linux, you can either
b.1) run "cmake CMakeLists.txt" in sbpl\cmake_build and then "make" in the same directory
(note: don't try to run cmake in sbpl. CMakeLists.txt file in there is for ROS make)
The binaries will be in the directory sbpl\cmake_build\bin
b.2) or create your own makefile.
c) For those using SBPL as part of ROS:
You can download the whole ROS package (see https://www.ros.org/wiki/ROS/Installation) and
just do "rosmake sbpl" within sbpl directory. The binaries will appear in sbpl\bin directory
Usage:
Examples for how to use SBPL is in src/test/main.cpp.
Please follow the examples carefully - it will save you a lot of debugging time since currently there is no documentation available for the library. The library contains a number of planning problem examples, stored as ascii files. These files (with extension .cfg) should be passed in as arguments into the main function in main.cpp. The files can be found in env_examples directory.
Note: in main function in main.cpp, you can comment and uncomment the planners you want to run.
The xytheta lattice planners require two arguments: cfg file and mprim file. The latter specifies the
motion primitives according to which the robot can move in x,y,theta. Motion primitives files can be found in sbpl/matlab/mprim directory
Finally, few visualization scripts can be found in sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be used to visualize the path found by xytheta lattice planner. This functions takes in .cfg file that specified environment and sol.txt file that was generated within main.cpp by xythetalattice planners.
Note: when running a test_sbpl executable compiled using rosmake option, all the normal output is disabled. If you want to run sbpl in standalone mode (as opposed as calling from ROS node), then you should compile ROS (either in cmake_build for linux or win32_build for windows). Then, when you run test_sbpl executable, it will print out standard messages and generate solution file in sol.txt as well as debug.txt with some debug info.
Links:
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment under ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.3.1 |
Last Updated | 2018-08-06 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.3.1 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Examples:
The following can be run from the directory containing test_sbpl,
which we assume is a build directory in the root of this project.
$ ./test_sbpl ../env_examples/nav3d/env1.cfg
Environment: xytheta; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=16
solution size=0
Solution is found
$ ./test_sbpl --env=2d ../env_examples/nav2d/env1.cfg #2d is needed here in order to use 2d config
Environment: 2d; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=22
Solution is found
$ ./test_sbpl --env=robarm --search-dir=forward --planner=rstar ../env_examples/robarm/env1_6d.cfg
Environment: robarm; Planner: rstar; Search direction: forward
Initializing RSTARPlanner...
start planning...
done planning
size of solution=44
Solution is found
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.
Repository Summary
Checkout URI | https://github.com/sbpl/sbpl |
VCS Type | git |
VCS Version | 1.3.1 |
Last Updated | 2018-08-06 |
Dev Status | MAINTAINED |
CI status | No Continuous Integration |
Released | RELEASED |
Tags | No category tags. |
Contributing |
Help Wanted (0)
Good First Issues (0) Pull Requests to Review (0) |
Packages
Name | Version |
---|---|
sbpl | 1.3.1 |
README
I. Building, Installing, and Using SBPL
SBPL is available as a standalone software library. SBPL itself has no
dependencies other than the C/C++ standard library.
These build and install instructions are primarily for Linux. For other
operating systems, CMake can generate the platform-specific build and project
files necessary for building SBPL.
Versions of ROS older than Fuerte may contain packages that depend on a ROS
package version of SBPL. The recommended method to install SBPL is to install
it as a standard system library. However, if you wish to use the old ROS
package version of SBPL, you may follow these instructions.
1. Building and Installing SBPL from source
1.1 Build SBPL
SBPL uses git as its version control system. From the directory where
you want the SBPL source to reside, clone the latest source from
https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, build the SBPL library using standard
CMake build conventions:
mkdir build
cd build
cmake ..
make
1.2 Install SBPL
Install the built library and headers onto your local system
(usually into /usr/local):
sudo make install
2. Installing SBPL from pre-built binary package
A pre-built Debian package exists on Linux for ROS distributions
Fuerte and newer. To install the Debian, run:
sudo apt-get install ros-distro-sbpl
where distro is the name of your ROS distribution. This will install
the SBPL library and associated development headers alongside other
ROS components (in /opt/ros/distro on Ubuntu distributions). A
pkg-config file is also included to allow you to locate the SBPL
library components in your build system.
3. Build your (ROS) package with SBPL as a dependency (CMake)
In the CMakeLists.txt for your (ROS) package, the following lines are
needed to find the installed SBPL files:
find_package(PkgConfig REQUIRED)
pkg_check_modules(SBPL REQUIRED sbpl)
include_directories(${SBPL_INCLUDE_DIRS})
link_directories(${SBPL_LIBRARY_DIRS})
Then, after you've declared your binaries, you need to link them
against SBPL with the following line:
target_link_libraries(your-binary-here ${SBPL_LIBRARIES})
4. Installing and Using SBPL as a ROS package
The ROS package version of SBPL was deprecated with the release of ROS
Fuerte. However, packages in ROS Electric may still require the ROS
package version of SBPL.
4.1 Install SBPL
4.1.1 Source install
SBPL uses git as its version control system. From the
directory where you want the SBPL source to reside, clone the
latest source from https://github.com/sbpl/sbpl:
git clone https://github.com/sbpl/sbpl.git
In the source directory, checkout the electric branch of the
repository to revert to the old ROS package version:
git checkout -b electric
Ensure that SBPL is on your ROS_PACKAGE_PATH and type:
rosmake sbpl
4.1.2 Binary install
SBPL is also available as a pre-built Debian in ROS Electric.
To instal the Debian, run:
sudo apt-get install ros-electric-arm-navigation
4.2 Build your ROS package with SBPL as a depency (rosbuild)
In the manifest.xml for your package, you need to add the
following line to declare the SBPL package as a dependency:
<depend package="sbpl"/>
II. Usage
Examples for how to use SBPL are in src/test/main.cpp. Please follow the
examples carefully. The library contains a number of planning problem
examples, stored as ascii files. These files (with extension .cfg) should
be passed in as arguments into the main function in main.cpp. The files
can be found in env_examples directory.
Command-line usage for the test_sbpl program can be viewed by passing '-h'
as argument to the executable.
Examples:
The following can be run from the directory containing test_sbpl,
which we assume is a build directory in the root of this project.
$ ./test_sbpl ../env_examples/nav3d/env1.cfg
Environment: xytheta; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=16
solution size=0
Solution is found
$ ./test_sbpl --env=2d ../env_examples/nav2d/env1.cfg #2d is needed here in order to use 2d config
Environment: 2d; Planner: arastar; Search direction: backward
Initializing ARAPlanner...
start planning...
done planning
size of solution=22
Solution is found
$ ./test_sbpl --env=robarm --search-dir=forward --planner=rstar ../env_examples/robarm/env1_6d.cfg
Environment: robarm; Planner: rstar; Search direction: forward
Initializing RSTARPlanner...
start planning...
done planning
size of solution=44
Solution is found
Motion primitives files can be found in sbpl/matlab/mprim directory.
Finally, few visualization scripts can be found in
sbpl/matlab/visualization. In particular, plot_3Dpath.m function can be
used to visualize the path found by xytheta lattice planner. This
functions takes in .cfg file that specified environment and sol.txt file
that was generated within main.cpp by xythetalattice planners.
Note: If you compile the library with the ROS symbol defined, all text
output will be redirected to ROS logging constructions. Without the ROS
symbol defined, SBPL will print messages to stdout and test_sbpl will
generate a solution file, sol.txt, as well as a debugging information
file, debug.txt
III. Links
These instructions and more tutorials can be found at www.sbpl.net
For more information and documentation on SBPL visit:
http://www.ros.org/wiki/sbpl
For more information and documentation on using the x,y,theta environment
available in ROS visit:
http://www.ros.org/wiki/sbpl_lattice_planner
CONTRIBUTING
No CONTRIBUTING.md found.