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Main Authors: Toshani, Hamid, Petangoda, Janith, Samarakoon, Chatura, Stanley-Marbell, Phillip
Format: Preprint
Published: 2025
Subjects:
Online Access:https://arxiv.org/abs/2501.16473
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author Toshani, Hamid
Petangoda, Janith
Samarakoon, Chatura
Stanley-Marbell, Phillip
author_facet Toshani, Hamid
Petangoda, Janith
Samarakoon, Chatura
Stanley-Marbell, Phillip
contents Uniform temperature distribution in Selective Laser Sintering (SLS) is essential for producing durable 3D prints. Achieving uniformity requires a laser power control system that minimises deviation of the printing temperatures from the target temperature. Because the estimate of the actual process temperature is an input to the laser power control, uncertainty in the estimate of the actual temperature can lead to fluctuations in laser power that affect the thermal performance of the SLS. This article investigates the sensitivity of a laser power control system to temperature measurement uncertainty. This article evaluates the effectiveness of two methods for quantifying the effect of input uncertainty on a SLS laser power control system: a recent innovation in uncertainty-tracked architecture and traditional Monte Carlo simulation. We show that recent advances in computer architecture for arithmatic on probability distributions make it possible for the first time, to perform control system uncertainty analysis with latencies under 30 ms, while achieving the same level of uncertainty analysis as Monte Carlo methods with latencies that are two orders of magnitude slower.
format Preprint
id arxiv_https___arxiv_org_abs_2501_16473
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sensitivity Analysis of the Laser Power Control System to Measurement Noise in SLS 3D Printers
Toshani, Hamid
Petangoda, Janith
Samarakoon, Chatura
Stanley-Marbell, Phillip
Systems and Control
Uniform temperature distribution in Selective Laser Sintering (SLS) is essential for producing durable 3D prints. Achieving uniformity requires a laser power control system that minimises deviation of the printing temperatures from the target temperature. Because the estimate of the actual process temperature is an input to the laser power control, uncertainty in the estimate of the actual temperature can lead to fluctuations in laser power that affect the thermal performance of the SLS. This article investigates the sensitivity of a laser power control system to temperature measurement uncertainty. This article evaluates the effectiveness of two methods for quantifying the effect of input uncertainty on a SLS laser power control system: a recent innovation in uncertainty-tracked architecture and traditional Monte Carlo simulation. We show that recent advances in computer architecture for arithmatic on probability distributions make it possible for the first time, to perform control system uncertainty analysis with latencies under 30 ms, while achieving the same level of uncertainty analysis as Monte Carlo methods with latencies that are two orders of magnitude slower.
title Sensitivity Analysis of the Laser Power Control System to Measurement Noise in SLS 3D Printers
topic Systems and Control
url https://arxiv.org/abs/2501.16473