Abstract: A method for processing an interrupted workpiece includes providing a dynamic control model defining the processing characteristics of a processing tool throughout a processing run; providing a partially processed workpiece; determining an extent of processing metric for the partially processed workpiece; and determining at least one operating recipe parameter of the processing tool based on the dynamic control model and the extent of processing metric. A manufacturing system includes a processing tool and a process controller. The processing tool is adapted to process a partially processed workpiece in accordance with an operating recipe. The process controller is adapted to determine an extent of processing metric for the partially processed workpiece and determine at least one parameter of the operating recipe based on a dynamic control model defining the processing characteristics of the processing tool throughout a processing run and the extent of processing metric.

Abstract: A method and an apparatus for performing a process control using partial measurement data. A process operation is performed on a semiconductor wafer. Inline metrology data related to the process of the semiconductor wafer is acquired. A partial measurement data acquisition process is performed based upon the inline metrology data, the partial measurement data acquisition process comprising determining a time period for acquiring the inline metrology data, determining a number of wafers to be sampled based upon the time period, and determining a number of wafer sites for data acquisition. At least one of a feedback adjustment on a second semiconductor wafer and a feed-forward adjustment relating to a subsequent processing of the first semiconductor wafer based upon the partial measurement data acquisition process is performed.

Abstract: A method and an apparatus for performing feed-forward correction during semiconductor wafer manufacturing. A first process on a semiconductor wafer is performed. Integrated metrology data related to the first process of the semiconductor wafer is acquired. An integrated metrology feed-forward process is performed based upon the integrated metrology data, the integrated metrology feed-forward process comprising identifying at least one error on the semiconductor wafer based upon the integrated metrology data related to the first process of the semiconductor wafer and performing an adjustment process to a second process to be performed on the wafer to compensate for the error. The second process on the semiconductor wafer is performed based upon the adjustment process.

Abstract: A method for prioritizing production flow includes processing a plurality of manufactured items in a process flow; measuring characteristics of a plurality of manufactured items in the process flow; estimating performance grades for the plurality of manufactured items based on the measured characteristics; grouping the manufactured items with like estimated performance grades; assigning priorities to groups of manufactured items with like estimated performance grades; and directing the plurality of manufactured items through the process flow based on the assigned priorities. A manufacturing system includes a plurality of processing tools adapted to process a plurality of manufactured items in a process flow, a metrology tool, and a process control server. The metrology tool is adapted to measure characteristics of a plurality of manufactured items in the process flow.

Abstract: A method and an apparatus for performing modeling of batch dynamics in processing of semiconductor wafers. The method includes performing the process on the first semiconductor wafer in a lot, the process being controlled by a tool model, and acquiring integrated metrology data related to the process of the first semiconductor wafer using an integrated metrology tool. The method further includes performing a lot dynamic modeling process based upon an analysis of the integrated metrology data, the lot dynamic modeling process comprising adjusting the tool model based upon analysis of the integrated metrology data, and performing the process on a second semiconductor wafer in the lot based upon the adjusted tool model.

Abstract: A method and an apparatus for dynamic targeting for a process control system. A process step is performed upon a first workpiece in a batch based upon a process target setting. The process target setting comprises at least one parameter relating to a target characteristic of the first workpiece. Manufacturing data relating to processing of the first workpiece is acquired. The manufacturing data comprises at least one of a metrology data relating to the processed first workpiece and a tool state data relating to the tool state of a processing tool. Electrical data relating to the processed first workpiece is acquired at least partially during processing of a second workpiece in the batch. The process target setting is adjusted dynamically based upon a correlation of the electrical data with the manufacturing data.

Abstract: A method includes processing a plurality of workpieces in accordance with an operating recipe. A defectivity metric is determined based on the operating recipe. A sampling plan for measuring a characteristic of selected workpieces processed using the operating recipe is determined based on the defectivity metric. A manufacturing system includes a process tool and a sampling controller. The process tool is configured to process a plurality of workpieces in accordance with an operating recipe. The sampling controller is configured to determine a defectivity metric based on the operating recipe and determine a sampling plan for measuring a characteristic of selected workpieces processed using the operating recipe based on the defectivity metric.

Abstract: A method for determining output characteristics of a workpiece includes generating a tool state trace related to the processing of a workpiece in a tool; comparing the generated tool state trace to a library of reference tool state traces, each reference tool state trace having an output characteristic metric; selecting a reference tool state trace closest to the generated tool state trace; and determining an output characteristic of the workpiece based on the output characteristic metric associated with the selected reference tool state trace. A manufacturing system includes a tool and a tool state monitor. The tool is adapted to process a workpiece.

Abstract: A method for controlling the flow of wafers through a process flow includes monitoring operating states of a plurality of processing tools adapted to process wafers; measuring a characteristic of a particular incoming wafer; identifying a particular processing tool having an operating state complimentary to the measured characteristic; and routing the particular incoming wafer to the particular processing tool for processing. A manufacturing system includes a plurality of processing tools adapted to process wafers and a process control server. The process control server is adapted to access metrology data related to a characteristic of a particular incoming wafer, identify a particular processing tool having an operating state complimentary to the characteristic, and route the particular incoming wafer to the particular processing tool for processing.

Abstract: A method includes measuring a characteristic of a workpiece at a plurality of locations. A uniformity profile is generated based on the characteristic measurements. At least one acceptable region of the workpiece is identified based on the uniformity profile. At least one unacceptable region of the workpiece is identified based on the uniformity profile. The uniformity profile is filtered to remove at least a portion of the characteristic measurements associated with the second unacceptable region. At least one parameter of an operating recipe for performing a process on the workpiece is determined based on the filtered uniformity profile.

Abstract: A method comprising performing an etch process recipe comprised of an endpoint etch process and a timed over-etch process on each of a first plurality of substrates to form at least one opening in each layer of insulating material, determining a duration of the endpoint etch process performed on the first plurality of substrates, determining a duration of the timed over-etch process of the etch process recipe to be performed on a second plurality of substrates based upon the determined duration of the endpoint etch process performed on the first plurality of substrates, and performing the etch process recipe comprised of the endpoint etch process and the timed over-etch process of the determined duration on the second plurality of semiconducting substrates.

Abstract: A processing line includes a processing tool, a metrology tool, a processing monitor, and a sampling controller. The processing tool is configured to process workpieces. The metrology tool is configured to measure an output characteristic of selected workpieces in accordance with a sampling plan. The processing monitor is configured to monitor the processing of at least one workpiece in the processing tool to generate a fingerprint and determine a processing metric based on the fingerprint. The sampling controller is configured to receive the processing metric and determine the sampling plan for the metrology tool based on the processing metric. A method for processing workpieces includes processing a plurality of workpieces in a processing tool. A characteristic of selected workpieces is measured in accordance with a sampling plan. The processing of at least one workpiece in the processing tool is monitored to generate a fingerprint. A processing metric is determined based on the fingerprint.

Abstract: A method and an apparatus for combining integrated and offline metrology data for process control. A process operation on a first semiconductor wafer within a first lot of semiconductor wafers is performed. Integrated metrology data from the first semiconductor wafer is acquired, the integrated metrology data comprising inline metrology data. A dynamic time process control based upon the integrated metrology data is performed, the dynamic time process control comprising a wafer-to-wafer feedback loop. A second semiconductor wafer within the first lot is processed based upon the dynamic time process. Offline metrology data from at least one of the first semiconductor wafer and the second semiconductor wafer from the lot is acquired. A constant time process control based upon the offline metrology data and the integrated metrology data is performed, the constant time comprising performing a lot-to-lot feedback process.

Abstract: The present invention is directed to an automated method of controlling critical dimensions of features by controlling the stepper exposure dose, and a system for accomplishing same. In one embodiment, the method comprises measuring a critical dimension (FICD) of a plurality of features formed in a process layer, and providing the measured critical dimensions of the features to a controller that determines, based upon the measured critical dimensions, an exposure dose of an exposure process to be performed on at least one subsequently processed wafer. In another embodiment, the method comprises measuring a critical dimension (DICD) of a plurality of features formed in a patterned layer of photoresist, providing the measured critical dimensions of the features in the patterned layer of photoresist to a controller that determines, based upon the measured critical dimensions, an exposure dose of an exposure process to be performed on at least one subsequently processed wafer.

Abstract: A method for controlling a manufacturing system includes processing workpieces in a plurality of tools; initiating a baseline control script for a selected tool of the plurality of tools; providing context information for the baseline control script; determining a tool type based on the context information; selecting a control routine for the selected tool based on the tool type; and executing the control routine to generate a control action for the selected tool. A manufacturing system includes a plurality of tools adapted to process workpieces, a control execution manager, and a control executor. The control execution manager is adapted to initiate a baseline control script for a selected tool of the plurality of tools and provide context information for the baseline control script.

Abstract: A method and an apparatus for correlating error data with detect data. A semiconductor wafer in a first lot is processed. Defect data based upon analysis of the processed semiconductor wafer is acquired. Electrical test data based upon analysis of the processed semiconductor wafer is acquired. The electrical test data is acquired by performing a wafer electrical testing process on the processed semiconductor wafer. The electrical test data is correlated with the defect data to produce correlated data. At least one of the following is performed: a yield prediction or the performance prediction of a second lot based upon the correlated data. The yield prediction comprises predicting a percentage yield of acceptable semiconductor wafers in the second lot. The performance prediction comprises predicting the performance of the acceptable semiconductor wafers.

Abstract: In one illustrative embodiment, the method comprises providing a wafer, forming a plurality of die above the wafer, identifying a plurality of good die and at least one non-useful die from the plurality of die, and performing a test process on the at least one non-useful die but not on the good die. In another aspect, the present invention is directed to a system that comprises a metrology tool for receiving a wafer having a plurality of die formed thereabove and identifying a plurality of good die and at least one non-useful die from the plurality of die formed above the wafer, and a process tool for performing a test process on the at least one non-useful die on the wafer but not on the plurality of good die.

Abstract: In one illustrative embodiment, the method includes providing a wafer including at least one non-production area, forming a process layer above the wafer, forming a masking layer above the process layer, the masking layer being patterned so as to expose a portion of the process layer formed above the at least one non-production area, and performing a process operation on the exposed portion of the process layer formed above the at least one non-production area. In another aspect, the present invention is directed to a system that includes a controller for identifying at least one non-production area of a wafer, a photolithography tool for forming a masking layer above the process layer, the masking layer being patterned so as to expose a portion of the process layer formed above the at least one non-production area, and an etch tool for performing an etching process on the exposed portion of the process layer formed above the at least one non-production area.

Abstract: A technique for processing a wafer in a semiconductor manufacturing process are disclosed. The method comprises first collecting a set of processing rate data from a multi-station processing tool, the set including process rate data from at least two stations in the processing tool. The collected processing rate data is then communicated to a controller that autonomously compares the processing rate data to determine whether to adjust a process parameter. The method then adjusts the process parameter for at least one station to match the process endpoint for the at least one station.

Abstract: A method of compensating for across-wafer variations in photoresist thickness is provided. The method comprises providing a wafer having a process layer formed there-above, forming a layer of photoresist above the process layer, measuring a thickness of the layer of photoresist at a plurality of locations to result in a plurality of thickness measurements, providing the thickness measurements to a controller that determines, based upon the thickness measurements, an exposure dose of an exposure process to be performed on the layer of photoresist, and performing the exposure process on the layer of photoresist using the determined exposure dose. This exposure dose may be varied on a flash-by-flash basis as the stepper tool “steps” across the surface of wafers. That is, the exposure dose for a group of flashes, or for each flash, may be varied in response to the thickness measurements.