This page has been translated automatically.
Video Tutorials
Interface
Essentials
Advanced
How To
Professional (SIM)
UnigineEditor
Interface Overview
Assets Workflow
Settings and Preferences
Working With Projects
Adjusting Node Parameters
Setting Up Materials
Setting Up Properties
Lighting
Landscape Tool
Sandworm
Using Editor Tools for Specific Tasks
Extending Editor Functionality
Built-in Node Types
Nodes
Objects
Effects
Decals
Light Sources
Geodetics
World Nodes
Sound Objects
Pathfinding Objects
Players
Programming
Fundamentals
Setting Up Development Environment
Usage Examples
C++
C#
UnigineScript
UUSL (Unified UNIGINE Shader Language)
Plugins
File Formats
Materials and Shaders
Rebuilding the Engine Tools
GUI
Double Precision Coordinates
API
Containers
Common Functionality
Controls-Related Classes
Engine-Related Classes
Filesystem Functionality
GUI-Related Classes
Math Functionality
Node-Related Classes
Objects-Related Classes
Networking Functionality
Pathfinding-Related Classes
Plugins-Related Classes
IG Plugin
CIGIConnector Plugin
Rendering-Related Classes
Content Creation
Content Optimization
Materials
Material Nodes Library
Miscellaneous
Input
Math
Matrix
Textures
Art Samples
Tutorials
Warning! This version of documentation is OUTDATED, as it describes an older SDK version! Please switch to the documentation for the latest SDK version.
Warning! This version of documentation describes an old SDK version which is no longer supported! Please upgrade to the latest SDK version.

Unigine::JointWheel Class

Header: #include <UniginePhysics.h>
Inherits from: Joint

This class is used to create ray-cast wheels. Both a frame and a wheel are rigid bodies. There is no need to assign a shape to the wheel: ray casting is used to detect collision of the wheel with a surface.

Example#

The following code illustrates connection of two rigid bodies (frame and wheel) using a wheel joint.

Source code (C++)
include <UniginePhysics.h>

/* .. */

JointWheelPtr joint = JointWheel::create(frame, wheel);

// setting joint anchor coordinates
joint->setWorldAnchor(wheel->getObject()->getWorldTransform() * Vec3(0.0f));

// setting joint axes coordinates
joint->setWorldAxis0(vec3(0.0f,0.0f,1.0f));
joint->setWorldAxis1(vec3(0.0f,1.0f,0.0f));

// setting linear damping and spring rigidity
joint->setLinearDamping(200.0f);
joint->setLinearSpring(100.0f);

// setting lower and upper suspension ride limits [-1.0; 0.0]
joint->setLinearLimitFrom(-1.0f);
joint->setLinearLimitTo(0.0f);

// setting target suspension height 
joint->setLinearDistance(0.5f);

// setting maximum angular velocity and torque
joint->setAngularVelocity(-20.0f);
joint->setAngularTorque(10.0f);

// setting wheel parameters
joint->setWheelRadius(0.5f);
joint->setWheelMass(4.0f);
joint->setWheelThreshold(0.1f);

// setting tyre friction parameters
joint->setTangentFriction(4.0f);
joint->setBinormalFriction(5.0f);

// setting number of iterations
joint->setNumIterations(8);

See Also#

  • Creating a Car with Wheel Joints usage example.
  • UnigineScript API sample <UnigineSDK>/data/samples/joints/wheel_00
  • UnigineScript API sample <UnigineSDK>/data/samples/physics/car_02

JointWheel Class

Members


static JointWheelPtr create ( ) #

Constructor. Creates a wheel joint with an anchor at the origin of the world coordinates.

static JointWheelPtr create ( const Ptr<Body> & body0, const Ptr<Body> & body1 ) #

Constructor. Creates a wheel joint connecting two given bodies. An anchor is placed between centers of mass of the bodies.

Arguments

  • const Ptr<Body> & body0 - Frame to be connected with the joint.
  • const Ptr<Body> & body1 - Wheel to be connected with the joint.

static JointWheelPtr create ( const Ptr<Body> & body0, const Ptr<Body> & body1, const Math::Vec3 & anchor, const Math::vec3 & axis0, const Math::vec3 & axis1 ) #

Constructor. Creates a wheel joint connecting two given bodies with specified suspension and spindle axis coordinates and an anchor placed at specified coordinates.

Arguments

  • const Ptr<Body> & body0 - Frame to be connected with the joint.
  • const Ptr<Body> & body1 - Wheel to be connected with the joint.
  • const Math::Vec3 & anchor - Anchor coordinates.
  • const Math::vec3 & axis0 - Suspension axis coordinates.
  • const Math::vec3 & axis1 - Wheel spindle axis coordinates.

void setAngularDamping ( float damping ) #

Sets an angular damping of the joint (wheel rotation damping).

Arguments

  • float damping - Angular damping. If a negative value is provided, 0 will be used instead.

float getAngularDamping ( ) #

Returns the angular damping of the joint (wheel rotation damping).

Return value

Angular damping.

void setAngularTorque ( float torque ) #

Sets a maximum torque of the attached angular motor.

Arguments

  • float torque - Maximum torque. If a negative value is provided, 0 will be used instead.

float getAngularTorque ( ) #

Returns the maximum torque of the attached angular motor.

Return value

Maximum torque.

void setAngularVelocity ( float velocity ) #

Sets a maximum velocity of wheel rotation.

Arguments

  • float velocity - Velocity in radians per second.

float getAngularVelocity ( ) #

Returns the target velocity of wheel rotation.

Return value

Target velocity in radians per second.

void setAxis00 ( const Math::vec3 & axis00 ) #

Sets coordinates of suspension axis, along which a wheel moves vertically. This is a shock absorber.

Arguments

  • const Math::vec3 & axis00 - Suspension axis.

Math::vec3 getAxis00 ( ) #

Returns suspension axis coordinates.

Return value

Suspension axis.

void setAxis10 ( const Math::vec3 & axis10 ) #

Sets a wheel spindle axis in coordinates of the frame (body 0): an axis around which a wheel rotates when moving forward (or backward).

Arguments

  • const Math::vec3 & axis10 - Wheel spindle axis in coordinates of the frame (body 0).

Math::vec3 getAxis10 ( ) #

Returns the wheel spindle axis in coordinates of the frame (body 0).

Return value

Wheel spindle axis in coordinates of the frame (body 0).

void setAxis11 ( const Math::vec3 & axis11 ) #

Sets a wheel spindle axis in coordinates of the wheel (body 1): an axis around which a wheel rotates when steering.

Arguments

  • const Math::vec3 & axis11 - Wheel spindle axis in coordinates of the wheel (body 1).

Math::vec3 getAxis11 ( ) #

Returns the wheel spindle in coordinates of the wheel (body 1).

Return value

Wheel spindle axis in coordinates of the wheel (body 1).

void setBinormalAngle ( float angle ) #

Sets a coefficient specifying how fast the optimal lateral force can be achieved. The larger this value, the more is the impulse produced by the tire.

Arguments

  • float angle - Coefficient characterizing the tire lateral impulse. If a negative value is provided, 0 will be used instead.

float getBinormalAngle ( ) #

Returns the coefficient specifying how fast the optimal lateral force can be achieved. The larger this value, the more is the impulse produced by the tire.

Return value

Coefficient characterizing the tire lateral impulse.

void setBinormalFriction ( float friction ) #

Sets a lateral (sideways) friction of the tire.

Arguments

  • float friction - Lateral friction. If a negative value is provided, 0 will be used instead.

float getBinormalFriction ( ) #

Returns the lateral (sideways) friction of the tire.

Return value

Lateral friction.

Math::vec3 getContactNormal ( ) #

Returns a normal of a point of contact with the ground, in world coordinates.

Return value

Normal.

Ptr<Object> getContactObject ( ) #

Returns an object representing the ground.

Return value

Ground object.

Math::Vec3 getContactPoint ( ) #

Returns a point of contact with the ground, in world coordinates.

Return value

Point coordinates.

Ptr<Shape> getContactShape ( ) #

Returns a shape of the object representing the ground.

Return value

Shape of the ground object.

int getContactSurface ( ) #

Returns a surface of a ground object, which is in contact.

Return value

Surface number.

void setCurrentAngularVelocity ( float velocity ) #

Sets the rotation velocity for the attached wheels. For example, it allows to reset it to zero and stop the car when necessary.

Arguments

  • float velocity - Angular velocity in radians per second.

float getCurrentAngularVelocity ( ) #

Returns the current rotation velocity of the attached wheels.

Return value

Current angular velocity in radians per second.

void setCurrentLinearDistance ( float distance ) #

Sets suspension compression (i.e. the length of the suspension).

Arguments

  • float distance - Suspension length in units.

float getCurrentLinearDistance ( ) #

Returns the current suspension compression (i.e. the length of the suspension).

Return value

Current suspension length in units.

float getCurrentSlipAngle ( ) #

Returns the current angle between the wheel direction and the frame direction.

Return value

Current slip angle in degrees.

float getCurrentSlipRatio ( ) #

Returns the current ratio of wheel spin to ground speed.

Return value

Current slip ratio in percents. 0 means that the velocities are equal. If the throttle is pressed, the value will be positive. If the brake is pressed, the value will be negative.

void setPhysicsIntersectionMask ( int mask ) #

Sets a physics intersection mask for the joint.

Arguments

  • int mask - Integer, each bit of which is a mask.

int getPhysicsIntersectionMask ( ) #

Returns an physics intersection mask mask of the joint.

Return value

Integer, each bit of which is a mask.

void setLinearDamping ( float damping ) #

Sets a linear damping of the suspension.

Arguments

  • float damping - Linear damping. If a negative value is provided, 0 will be used instead.

float getLinearDamping ( ) #

Returns the linear damping of the suspension.

Return value

Linear damping.

void setLinearDistance ( float distance ) #

Sets a target height of the suspension.

Arguments

  • float distance - Height in units.

float getLinearDistance ( ) #

Returns the target height of the suspension.

Return value

Target height in units.

void setLinearLimitFrom ( float from ) #

Sets a low limit of the suspension ride.

Arguments

  • float from - Limit in units.

float getLinearLimitFrom ( ) #

Returns the low limit of the suspension ride.

Return value

Low limit in units.

void setLinearLimitTo ( float to ) #

Sets a high limit of the suspension ride.

Arguments

  • float to - Limit in units.

float getLinearLimitTo ( ) #

Returns the high limit of the suspension ride.

Return value

High limit in units.

void setLinearSpring ( float spring ) #

Sets a rigidity coefficient of the suspension.

Arguments

  • float spring - Rigidity coefficient. If a negative value is provided, 0 will be used instead.

float getLinearSpring ( ) #

Returns the rigidity coefficient of the suspension.

Return value

Rigidity coefficient.

void setTangentAngle ( float angle ) #

Sets a coefficient specifying how fast the optimal longitudinal force can be achieved. The larger this value, the more is the impulse produced by the tire.

Arguments

  • float angle - Coefficient characterizing the tire longitudinal impulse. If a negative value is provided, 0 will be used instead.

float getTangentAngle ( ) #

Returns the coefficient specifying how fast the optimal longitudinal force can be achieved. The larger this value, the more is the impulse produced by the tire.

Return value

Coefficient characterizing the tire longitudinal impulse.

void setTangentFriction ( float friction ) #

Sets a longitudinal (forward) friction of the tire.

Arguments

  • float friction - Longitudinal friction. If a negative value is provided, 0 will be used instead.

float getTangentFriction ( ) #

Returns the longitudinal (forward) friction of the tire.

Return value

Longitudinal friction.

void setWheelMass ( float mass ) #

Sets a mass of the attached wheel.
Notice
If g (Earth's gravity) equals to 9.8 m/s 2, and 1 unit equals to 1 m, the mass is measured in kilograms.

Arguments

  • float mass - Mass of the wheel. If a negative value is provided, 0 will be used instead.

float getWheelMass ( ) #

Returns the mass of the attached wheel.
Notice
If g (Earth's gravity) equals to 9.8 m/s 2, and 1 unit equals to 1 m, the mass is measured in kilograms.

Return value

Mass of the wheel.

void setWheelRadius ( float radius ) #

Sets a radius of the attached wheel.

Arguments

  • float radius - Radius of the wheel in units. If a negative value is provided, 0 will be used instead.

float getWheelRadius ( ) #

Returns the radius of the attached wheel.

Return value

Radius of the wheel in units.

void setWheelThreshold ( float threshold ) #

Sets a threshold difference between the wheel and ground velocities. When it is too small, the longitudinal force will be scaled down to prevent unnatural vibrations.

Arguments

  • float threshold - Difference threshold. If a negative value is provided, 0 will be used instead.

float getWheelThreshold ( ) #

Returns the threshold difference between the wheel and ground velocities. When it is too small, the longitudinal force will be scaled down to prevent unnatural vibrations.

Return value

Difference threshold.

void setWorldAxis0 ( const Math::vec3 & axis0 ) #

Sets suspension axis in the world coordinates.

Arguments

  • const Math::vec3 & axis0 - Suspension axis in the world coordinates.

Math::vec3 getWorldAxis0 ( ) #

Returns the suspension axis in the world coordinates.

Return value

Suspension axis in the world coordinates.

void setWorldAxis1 ( const Math::vec3 & axis1 ) #

Sets a wheel spindle axis in the world coordinates.

Arguments

  • const Math::vec3 & axis1 - Wheel spindle axis in the world coordinates.

Math::vec3 getWorldAxis1 ( ) #

Returns the wheel spindle axis in the world coordinates.

Return value

Wheel spindle axis in the world coordinates.
Last update: 2022-03-10
Build: ()