1. Field of the Invention
The present invention relates to a machine fault detection method. In particular, the present invention relates to a machine fault detection method that detects the root cause error generated from a plurality of machines used for processing wafer-in-process (WIP).
2. Description of the Related Art
The yield rate is a key index for the semiconductor fabricator. The yield rate represents the fabrication level and specification of the semiconductor fabricator. Furthermore, the yield rate also relates to the fabrication cost of the semiconductor fabricator. The yield rate affects the whole profit margin of the semiconductor fabricator. Therefore, how to improve the yield rate is of utmost concern for the semiconductor fabricator.
In the semiconductor fabrication industry, the wafer-in-process (WIP) must be processed by a plurality of semiconductor machines and a plurality of fabrication processes, such as chemical deposition, ion injection, mask, grind, etc. The fabrication process will affect the quality of the wafer-in-process. For example, the electrical quality and the status of the semiconductor fabrication machine determine the yield rate of the wafer-in-process. Therefore, if an abnormal condition can be detected in advance, the problem cab be solved early and the fabrication cost resulted from reduced yield rate can be kept down.
The methods for checking and measuring the yield rate of the wafer-in-process have been developed. For example, Taiwan patent TW 1229915 discloses a method for analyzing the equipment correlation of the yield rate of the semiconductor fabrication machine, a system thereof, a semiconductor fabrication method thereof, and a storage medium for storing the computer program of executing the method. Reference is made to
However, the method of using the equipment correlation of the prior art can only be used to check the yield rate of a single semiconductor fabrication machine, or find out the relation between the yield rate or measurement values against a plurality of semiconductor fabrication machines in a single fabrication process. The method cannot analyze the yield rate affected by a plurality of semiconductor fabrication machines in a plurality of fabrication processes. The method cannot find out the semiconductor fabrication machine that will affect the yield rate in the plurality of fabrication processes.
One particular aspect of the present invention is to provide a machine fault detection method. The method uses association rules to find out the root cause error from a plurality of semiconductor fabrication machines, the yield rate is improved, the fabrication cost is reduced, and the machine can be efficiently monitored.
The machine fault detection method is applied to a plurality of semiconductor fabrication machines. The semiconductor fabrication machines are used for processing at least one wafer-in-process (WIP). The method includes the flowing steps. A statistical database of the wafer-in-process is provided. An association survey calculation is performed to generate a support degree and a reliability degree. A threshold is selected. Whether the support degree and the reliability degree have surpassed the threshold or not is determined. When the support degree and the reliability degree have surpassed the threshold, a root cause error in the statistical database corresponded by the support degree and the reliability degree is determined. When the support degree and the reliability degree have not surpassed the threshold, the above steps are repeated.
The present invention uses the association rules in the statistical database, and has the following characteristics.
1. The root cause error of one or one set of semiconductor fabrication machines that cause the wafer-in-process being damaged is found to improve the yield rate, reduce the fabrication cost, and monitor the machines efficiently.
2. The threshold is determined (either by a user or by a computer) to find the root cause error of one or one set of semiconductor fabrication machines that cause the wafer-in-process being damaged. Thereby, the yield rate is improved, the fabrication cost is reduced, and the machine is efficiently monitored.
3. The machine default in the semiconductor fabrication processes can be detected efficiently to lower the risk. The potential risk is prevented and the safety is guaranteed.
For further understanding of the present invention, reference is made to the following detailed description illustrating the embodiments and examples of the present invention. The description is for illustrative purpose only and is not intended to limit the scope of the claim.
The drawings included herein provide a further understanding of the present invention. A brief introduction of the drawings is as follows:
Reference is made to
The semiconductor fabrication machines are formed by one or more dry etch machines, oven tube machines, thin-film deposition machines, and sputtering machines, etc. The dry etch machines are used for etching the polycrystalline, etching the oxidized layer, and etching the metal layer. The furnace tube machines are used for depositing the polycrystalline, and depositing the SiO2. The thin-film deposition machines are used for oxidizing the silicon nitride, strengthening the silicon nitride by plasma, strengthening the silicon nitride by penetrating UV rays, and strengthening SiO2, phosphorus glass, and boron phosphorus glass by plasma. The sputtering machines are used for metal-sputter.
Step S202 is executed. A statistical database of the wafer-in-process is provided. The statistical database records a plurality of fabrication process parameters of the semiconductor fabrication machines for the wafer-in-process. Reference is made to
Step S204 is executed. The chamber of the plurality of semiconductor fabrication machines for processing the wafer-in-process is labeled and listed (referencing to
Step S206 is executed. A data survey technology is executed (the data survey technology is also part of the association survey calculation). The data survey technology surveys the association data in the statistical database to generate a confidence degree. The reliability degree represents the ratio of the appeared collection set in the statistical database (i.e. the reliability degree is a ratio formed by the appeared plurality of association data against the plurality of association data in the statistical database.), referencing to
Step S208 is executed. A threshold is set. The threshold can be set by the user or the computer.
Step S210 is executed. Whether the support degree and the reliability degree have surpassed the threshold or not is determined. When the support degree and the reliability degree have surpassed the threshold, a next step is executed. When the support degree and the reliability degree have not surpass the threshold, the step S202 is repeated.
Step S212 is executed. A root cause error in the statistical database corresponded by the support degree and the reliability degree is determined. The root cause error is the machine fault (i.e. the root cause error shows a particular machine or particular set of machines that is at fault; thereby the responsible the one or one set of machines can be traced according to the root cause error. Please see computer display screen 706 of
Reference is made to
Reference is made to
The present invention uses the association rules in the statistical database, and has the following characteristics.
1. The root cause error of one or one set of semiconductor fabrication machines that cause the wafer-in-process being damaged is found.
2. The threshold is determined (either by a user or a computer) to find the root cause error of one or one set of semiconductor fabrication machines that cause the wafer-in-process to suffer defect which leads to lower wafer fabrication yield rate.
3. The machine default in the semiconductor fabrication processes can be detected efficiently to lower the risk. The yield rate is improved, the fabrication cost is reduced, the machine is efficiently monitored, and the potential risk is prevented and the safety is guaranteed.
The description above only illustrates specific embodiments and examples of the present invention. The present invention should therefore cover various modifications and variations made to the herein-described structure and operations of the present invention, provided they fall within the scope of the present invention as defined in the following appended claims.
Number | Date | Country | Kind |
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97116215 | May 2008 | TW | national |