Home
User Guide
This manual provides details on the features, functionality, and simulation methods available in Altair Radioss.
Explicit Structural Finite Element Analysis
In this section, available explicit features for different explicit analyses are presented.
Finite Elements
Solid Elements (/PROP/SOLID)
Solids hexahedron and tetrahedron with linear and quadratic interpolation functions are available in Radioss.

Welcome
What's New
View new features for Radioss 2024.1.
Overview
Radioss^® is a leading explicit finite element solver for crash and impact simulation.
Tutorials
Discover Radioss functionality with interactive tutorials.
User Guide
This manual provides details on the features, functionality, and simulation methods available in Altair Radioss.
- Run Radioss
  The Radioss solver can be executed using different methods described here.
- Explicit Structural Finite Element Analysis
  In this section, available explicit features for different explicit analyses are presented.
  - Time Step
    An explicit is solved by calculating results in small time increments or time steps. The size of the time step depends on many factors but is automatically calculated by Radioss.
  - Finite Elements
    - Solid Elements (/PROP/SOLID)
      Solids hexahedron and tetrahedron with linear and quadratic interpolation functions are available in Radioss.
    - Solid-Shell Elements (/PROP/TSHELL)
      The elements HA8, HEPH and BRICK20 can be transformed to solid-shell elements by setting constant the normal stress through the thickness.
    - Shell Elements
    - Beam Elements (/PROP/BEAM, /PROP/INT_BEAM)
      The two beam elements available in Radioss are used on one-dimensional structures and frames. It carries axial loads, shear forces, bending and torsion moments (contrary to the truss that supports only axial loads).
    - Springs
    - Mesh Recommendations
      Mesh recommendations in crash worthiness and in Implicit Analysis are covered.
    - Hourglass Formulations
      Under-integrated elements are very familiar in crash worthiness. In these elements, a reduced number of integration points are used to decrease the computation time. This simplification generates zero energy deformation modes, called hourglass modes.
    - Stress-Strain Computation Options (/PROP)
    - Radioss Coordinate System
  - Modeling Tools
  - Materials
    Different material tests could result in different material mechanic character.
  - Failure
  - Composites
    Composite materials consist of two or more materials combined each other. Most composites consist of two materials, binder (matrix) and reinforcement. Reinforcements come in three forms, particulate, discontinuous fiber, and continuous fiber.
  - Connections
  - Kinematic Constraints
    In Radioss, a kinematic condition is a nodal constraint applied to a set of nodes.
  - Interfaces
    Several interfaces are available in Radioss, this section deals with contact interfaces only. Each interface is distinguished with a type number.
  - Loads
  - Airbag Modeling
    Airbags are modeled as monitored volumes /MONVOL in several different ways.
  - Debugging Guidelines
  - Appendix
- Implicit Structural Finite Element Analysis
- Fluid and Fluid-Structure Simulation
  In this section, fluid and fluid-structure simulation is presented.
- Smooth Particle Hydrodynamics (SPH)
  The Smooth Particle Hydrodynamics method formulation is used to solve the equations of mechanics, when particles are free from a meshing grid.
- Multi-Domain Technique
  The objective of the Multi-Domain technique (also referred to as RAD2RAD) is to optimize the computing performances of large scale Radioss models.
- Design Optimization
  Optimization in Radioss was introduced in version 13.0. It is implemented by invoking the optimization capabilities of OptiStruct and simultaneously using the Radioss solver for analysis.
- Error Message Database
  This section is comprised of error messages in ascending numerical order.
- Engine Error Messages
- Warning Message Database
  This section is comprised of warning messages in ascending numerical order.
Reference Guide
This manual provides a detailed list of all the input keywords and options available in Radioss.
Example Guide
This manual presents examples solved using Radioss with regard to common problem types.
Verification Problems
This manual presents solved verification models.
Frequently Asked Questions
This section provides quick responses to typical and frequently asked questions regarding Radioss.
Theory Manual
This manual provides detailed information about the theory used in the Altair Radioss Solver.
User Subroutines
This manual describes the interface between Altair Radioss and user subroutines.

View All Altair HyperWorks Help

Solid Elements (/PROP/SOLID)

Solids hexahedron and tetrahedron with linear and quadratic interpolation functions are available in Radioss.

Linear elements are better in terms of time and memory consumption, especially due to the low number of integration points and a larger time step (

Δ t = \frac{L}{c}

):

TETRA4: $L = a \sqrt{\frac{2}{3}} = 0.816 a$
TETRA10: $L = a \frac{\sqrt{5 / 2}}{6} = 0.264 a$
BRICK8: $L = \frac{V o l u m e}{l \arg e s t f a c e a r e a}$
BRICK20: $L \approx \frac{t h i c k n e s s}{2}$

Table 1 summarizes the differences between theses elements. For BRICK8, the use of co-rotational formulation is explained in Element Library the Radioss Theory Manual; which can avoid the accumulation of an error, due to the updating process, especially when elements undergo large shear deformation. The formulation is not used by default for this element and should be activated by you.

Figure 1. Solid Finite Element Meshes in Radioss

Solid elements can be degenerated to overpass some meshing problems. Degenerated elements can be obtained by merging nodes on a same edge (hexahedron) or suppressing a middle node in a TETRA10. The use of degenerated elements is not recommended, but if they cannot be avoided due to complex geometry, it is important to respect the element symmetry to keep a homogenous mass distribution. Some examples of degenerated solid elements are shown in Figure 2.

Figure 2. Solid Elements Degeneration Examples

Table 1. Solid Elements
Mesh	Element Name	Number of Integration Points	Hourglass Formulation	Comments
	BRICK8	1x1x1 2x2x2	Penalty for the case of 1 IP	Use co-rotational formulation. Avoid hourglass TYPE 2
	HA8	from 2x2x2 to 9x9x9	---	Note the value used for the flag, `I`_cpre
	HEPH	1x1x1	Physical stabilization	Note the value used for the flag, `I`_cpre
	BRICK20	2x2x2 or 3x3x3	---	Too high cost element
	TETRA4	1	---	Shear locking in large deformation Low precision element
	TETRA10	4	---	High cost Good precision without shear locking