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Relying on local hardware and expensive HPC packs turns large-scale filter and waveguide optimizations into days-long queues.
Concurrent seat limits mean engineers waste valuable time simply waiting for their turn to solve, creating daily friction.
Manually handing off data between separate EM, thermal, and structural tools for complex components like RF-MEMS is slow and error-prone.
3D RF simulations scaled across thousands of CPUs
Fast parametric exploration at scale
Run thousands of geometric design variants simultaneously on 1000+ CPUs. Optimize mmWave passives in hours instead of weeks.
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Natively coupled multiphysics algorithms
Solve complex interactions—like RF, thermal, and structural mechanics in piezoelectric filters— in a single simulation. No manual coupling or data transfer.
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Zero hardware or license limits
Bypass local hardware constraints and eliminate seat contention entirely. Access to compute instantly when you need it.
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Programmatic control and automation
Take full control of your design exploration. Build custom, automated workflows and drive thousands of simulations programmatically via the Quanscient SDK.
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Example use cases
Automated design of substrate-integrated passives
Explore a massive design space for X-band, Ku-band, and mmWave components. Parameterize your designs with the Quanscient SDK and launch thousands of variants simultaneously to find the optimum design fast.
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Passive Components
Substrate-Integrated Waveguides
Fully automated workflows for tapers and transitions.
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RF FILTERS
Iris-Based Bandpass Filters
Parameterize cavity lengths and iris apertures to dial in target frequencies.
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RF FILTERS
High Rejection Notch Filters
Chambered designs simulated in parallel at massive scale.
Natively coupled multiphysics for deformed structures
When pure RF isn't enough, couple mechanical simulations to your RF simulations out-of-the-box. Capture the exact transfer characteristics of devices under physical stress.

Wearables
Twisted Coplanar Waveguides
Analyze transfer characteristics and RF performance shifts under various degrees of physical torsion.

Flexible RF
Bent Patch Antennas
Analyze transfer characteristics and RF performance shifts of deformed flexible structures.

AUTOMATION
Programmatic Deformation Sweeps
Use the Python SDK to parameterize mechanical stress. Script and sweep through hundreds of deformation states automatically.
See how it could work for you
Submit the form to talk with our experts—we'll respond within 1 business day. You'll learn:
- How Allsolve could fit your use case
- What results to expect (accuracy, runtime, design exploration capabilities and rough cost range)
- How it could plug into your workflow today
Interested in just seeing an on-demand demo? Watch the 3-minute demo here
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