Throughput improvement in semiconductor fabrication for 0.13?m technology

Semiconductor fabrication is known to be the one of the most complex manufacturing operations. This is due to total processing steps in semiconductor fabrication is as high as 1000 steps and the process will re-enter through same equipments multiple times. This will always pose a challenge to the op...

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Main Authors: Balakrishna P., Chik M.A., Ahmad I., Mohamad B.
Other Authors: 56736340400
Format: Conference paper
Published: 2023
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spelling my.uniten.dspace-303742023-12-29T15:47:08Z Throughput improvement in semiconductor fabrication for 0.13?m technology Balakrishna P. Chik M.A. Ahmad I. Mohamad B. 56736340400 24775125500 12792216600 57191513536 Cycle Time Priority Product Mixed Silicon Wafer Manufacturing Plant (Fab) Simulation Work In Progress (WIP) Computer software Fabrication Semiconducting silicon compounds Specifications Cycle time Priority Product Mixed Silicon Wafer Manufacturing Plant (Fab) Simulation Work in progress Silicon wafers Semiconductor fabrication is known to be the one of the most complex manufacturing operations. This is due to total processing steps in semiconductor fabrication is as high as 1000 steps and the process will re-enter through same equipments multiple times. This will always pose a challenge to the operational team to achieve goal for optimal cycle time and maximum output. One of the WIP (Work In Progress) management approach used to achieve this goal is to use the right WIP prioritization. In general, giving priority to respective WIP usually will result in faster cycle time to fulfill customer expectation. This is done by identifying specific products as priority 1 to be executed first and priority 2 next. The methodology in this research uses simulation software to configure a real 200mm semiconductor fabrication facility. The input parameters used in this analysis include technology product specification, products demand based on real market trend, manufacturing, and equipment specification and requirements. The results from this study re-instate that prioritization has direct impact to the overall product cycle time and monthly wafer output. The results in this study also shows that categorizing product into two types of priorities will improve the cycle time by 2.21% and monthly wafer output will increase by 2.1% compared to when the WIP were managed by the same priority. In conclusion, this is desirable because increasing 2.1% monthly output can easily contribute to increase revenue of more than USD 4 million per year, which is vital for company's survival in this competitive business. � 2011 IEEE. Final 2023-12-29T07:47:08Z 2023-12-29T07:47:08Z 2011 Conference paper 10.1109/RSM.2011.6088330 2-s2.0-83755228671 https://www.scopus.com/inward/record.uri?eid=2-s2.0-83755228671&doi=10.1109%2fRSM.2011.6088330&partnerID=40&md5=b16ea6304ffc98590c1cf714cbb554cc https://irepository.uniten.edu.my/handle/123456789/30374 6088330 228 231 Scopus
institution Universiti Tenaga Nasional
building UNITEN Library
collection Institutional Repository
continent Asia
country Malaysia
content_provider Universiti Tenaga Nasional
content_source UNITEN Institutional Repository
url_provider http://dspace.uniten.edu.my/
topic Cycle Time
Priority
Product Mixed
Silicon Wafer Manufacturing Plant (Fab)
Simulation
Work In Progress (WIP)
Computer software
Fabrication
Semiconducting silicon compounds
Specifications
Cycle time
Priority
Product Mixed
Silicon Wafer Manufacturing Plant (Fab)
Simulation
Work in progress
Silicon wafers
spellingShingle Cycle Time
Priority
Product Mixed
Silicon Wafer Manufacturing Plant (Fab)
Simulation
Work In Progress (WIP)
Computer software
Fabrication
Semiconducting silicon compounds
Specifications
Cycle time
Priority
Product Mixed
Silicon Wafer Manufacturing Plant (Fab)
Simulation
Work in progress
Silicon wafers
Balakrishna P.
Chik M.A.
Ahmad I.
Mohamad B.
Throughput improvement in semiconductor fabrication for 0.13?m technology
description Semiconductor fabrication is known to be the one of the most complex manufacturing operations. This is due to total processing steps in semiconductor fabrication is as high as 1000 steps and the process will re-enter through same equipments multiple times. This will always pose a challenge to the operational team to achieve goal for optimal cycle time and maximum output. One of the WIP (Work In Progress) management approach used to achieve this goal is to use the right WIP prioritization. In general, giving priority to respective WIP usually will result in faster cycle time to fulfill customer expectation. This is done by identifying specific products as priority 1 to be executed first and priority 2 next. The methodology in this research uses simulation software to configure a real 200mm semiconductor fabrication facility. The input parameters used in this analysis include technology product specification, products demand based on real market trend, manufacturing, and equipment specification and requirements. The results from this study re-instate that prioritization has direct impact to the overall product cycle time and monthly wafer output. The results in this study also shows that categorizing product into two types of priorities will improve the cycle time by 2.21% and monthly wafer output will increase by 2.1% compared to when the WIP were managed by the same priority. In conclusion, this is desirable because increasing 2.1% monthly output can easily contribute to increase revenue of more than USD 4 million per year, which is vital for company's survival in this competitive business. � 2011 IEEE.
author2 56736340400
author_facet 56736340400
Balakrishna P.
Chik M.A.
Ahmad I.
Mohamad B.
format Conference paper
author Balakrishna P.
Chik M.A.
Ahmad I.
Mohamad B.
author_sort Balakrishna P.
title Throughput improvement in semiconductor fabrication for 0.13?m technology
title_short Throughput improvement in semiconductor fabrication for 0.13?m technology
title_full Throughput improvement in semiconductor fabrication for 0.13?m technology
title_fullStr Throughput improvement in semiconductor fabrication for 0.13?m technology
title_full_unstemmed Throughput improvement in semiconductor fabrication for 0.13?m technology
title_sort throughput improvement in semiconductor fabrication for 0.13?m technology
publishDate 2023
_version_ 1806424306448596992
score 13.214268