Radtherm tutorials pdf

Our customers use TAITherm for an array of applications including the latest advancements in automotive, electronics, wearables, military technology, architecture and more. Our customers are pushing the boundaries of new technology by increasing usability, safety, and effectiveness in their industries through thermal simulations. TAITherm is fast—solving complex models in days instead of weeks without sacrificing accuracy.

Our users have extensive control over the trade-off between computation time and fidelity by modifying the mesh size, time-step size, material properties, and other inputs. TAITherm uses a multi-grid method for solving the heat transfer equations.

This method allows the solver to efficiently converge in a small number of iterations for even finely meshed models. The solver runs in parallel using local or distributed memory, easily making use of multi-core workstations or HPC resources.

TAITherm takes all modes of heat transfer into account. Gain a full and accurate picture of the thermal interactions your product will undergo. After our two-day training, you will be skilled at using the software on your own.

TAITherm is always getting better, with new features rolling out regularly. Here are some of the latest updates. Latest Features. TAITherm focuses on transient thermal analysis to deliver answers faster without sacrificing accuracy. Reduce your time-to-market while producing customer-satisfying designs.

Our Human Thermal Extension is a state-of-the-art technology for predicting human thermal comfort, safety, and effectiveness. It operates within our thermal analysis software, TAITherm, to provide a comprehensive simulation of human thermal sensation and thermoregulation under transient and asymmetric environmental conditions.

All thermoregulatory responses can be simulated based on many factors, including activity level. We have developed a comprehensive library of standard human models in various poses including both female and male physiologies. We have also developed an extensive clothing database for rapid model setup. The Battery Extension is designed to analyze the complexities of your batteries at a cell and pack level.

As a licensed component of TAITherm, it uses thermal simulation to determine the lifetime, durability, and safety of your battery system. You can verify design choices, and mitigate complications due to safety issues including thermal runaway and aging. The Exhaust Extension uses transient, thermal simulation to solve thermal challenges in one of the most complex systems in a vehicle — the exhaust system.

With a library of pre-built components and a simple set-up process, you can optimize your exhaust system design quickly, and understand how it will perform in hot soak or time-based scenarios. The Exhaust Extension is built to reduce set-up time, generate results quickly, and provide realistic solutions with transient simulation. The most efficient way to get started is to attend our two-day training.

After the training, you will be proficient at using the software on your own. Sensor response curve handy? With MuSES, you have reality at your fingertips. Because MuSES covers physics all the way back to heat sources and environmental loads, you can manage signature contrast and evaluate control kits for low observables design in any global location. Heat shields, cooling schemes, even camo surface treatments can be tested and evaluated for in-band radiance, replete with atmospheric attenuation along sensor line-of-sight.

Triage and prioritize your engineering with MuSES early in the development cycle. Place your sensor at any range, lookdown angle, and azimuth, whether at short range near ground or from aerial and satellite platforms. MuSES takes care of the rest, computing source radiance for both targets and backgrounds, direct, diffuse, and reflected solar, and spectral sources like sky radiance and water reflections.

The source radiance is then spectrally attenuated back to the sensor location. MuSES enables your team to test low observables designs, examine operational profiles for vulnerable, high-contrast situations, and even plan the best times for execution. Observing individuals, ships, vehicles, and aircraft on the ground from satellites and aerial platforms requires accurate atmospheric attenuation along the sensor line of sight.

MuSES employs calls to MODTRAN, the benchmark for physics-based atmospheric radiance computations, along with weather data and solar intensity to yield accurate renderings of ground-based assets. Solar loading, thermal shadows, and thermal lag are all computed over long time periods to accurately capture the temperature distribution and source radiances for the sensor wave band.

Rendering with multi-bounce ray tracing yields physically accurate and realistic contrast metrics. Using texture mapping, remote imagery can be used to impose a temperature distribution on terrains.

This enables you to drive an aerial scenario with realistic terrain temperature distribution on a faceted background component.

Targets can be placed on the terrain and rendered against complex, cluttered backgrounds. MuSES focuses on transient signature analysis to deliver answers faster without sacrificing accuracy.

Reduce your production time while providing optimized designs. Our Human Thermal Extension is a state-of-the-art technology for predicting human thermal comfort, safety, and effectiveness. It operates within our thermal analysis software, TAITherm, to provide a comprehensive simulation of human thermal sensation and thermoregulation under transient and asymmetric environmental conditions.

All thermoregulatory responses can be simulated based on many factors, including activity level. We have developed a comprehensive library of standard human models in various poses including both female and male physiologies.

We have also developed an extensive clothing database for rapid model setup. The Battery Extension is designed to analyze the complexities of your batteries at a cell and pack level. As a licensed component of TAITherm, it uses thermal simulation to determine the lifetime, durability, and safety of your battery system. You can verify design choices, and mitigate complications due to safety issues including thermal runaway and aging.

The Exhaust Extension uses transient, thermal simulation to solve thermal challenges in one of the most complex systems in a vehicle — the exhaust system. With a library of pre-built components and a simple set-up process, you can optimize your exhaust system design quickly, and understand how it will perform in hot soak or time-based scenarios. The Exhaust Extension is built to reduce set-up time, generate results quickly, and provide realistic solutions with transient simulation.