Abstract: The detection of a processing deviation in a multiple stage wafer processing system is achieved by assigning individual wafers a set of positional coordinates each time the wafer moves within the wafer processing system. In an example embodiment, a wafer is placed into a first processing stage and it is rotated to a certain angle of rotation. As the wafer moves from one processing stage to another the wafer is given a different angle of rotation; both the rotation angle and the wafer location are then recorded as a set of positional coordinates. The processed wafer is examined for surface deviations arising from variations in the processing parameters. The positional coordinates are used to develop a wafer movement map that aids in identifying the processing stage location where the deviation in the processing parameters occurred. An important advantage is the increased processing deviation traceability that the method brings to wafer processing.

Abstract: The movement of individual wafers in a semiconductor facility is tracked via a set of coordinates that include rotational points of reference on the wafer that coincide with the wafer's location in the processing line. In an example embodiment, the method includes imparting angles of rotation on the wafers in different stages of the processing system. The different angles of rotation on each wafer are collected as data along with the wafer location in the processing system and the tool/equipment identification code. The combined angle of rotation and wafer location data is used to map the path the wafer has traveled from the onset of processing. An important advantage of the invention is the increased control and traceability that the invention brings to wafer processing.

Abstract: A method for monitoring health of a tool includes receiving at least one tool parameter related to the processing of a workpiece in a tool; receiving a model selection trigger; selecting a tool health model based on the model selection trigger; generating at least one predicted tool parameter based on the selected tool health model; and generating a tool health rating for the tool based on a comparison between the measured tool parameter and the predicted tool parameter. A tool health monitor includes a library of tool health models, a model selector, and a fault detection and classification unit. The model selector is adapted to receive a model selection trigger and select a tool health model based on the model selection trigger.

Abstract: The present invention provides for a method and an apparatus for using a latency time period as a control input parameter. A manufacturing run of semiconductor devices is processed. Metrology data from the processed semiconductor devices is acquired. A latency analysis process is performed using the acquired metrology data. A feedback/feed-forward modification process is performed in response to the latency analysis process.

Abstract: A method and apparatus for performing manufacturing system analysis upon a manufacturing network. Real-time production data is collected. The real-time production data is stored in a static file database. A real-time data flow is emulated using said real-time production data from said static file database. A reactive function analysis is performed.

Abstract: A method and apparatus for providing fault detection in an Advanced Process Control (APC) framework. A first interface receives operational state data of a processing tool related to the manufacture of a processing piece. The state data is sent from the first interface to a fault detection unit. A fault detection unit determines if a fault condition exists with the processing tool based upon the state data. A predetermined action is performed on the processing tool in response to the presence of a fault condition. In accordance with one embodiment, the predetermined action is to shutdown the processing tool so as to prevent further production of faulty wafers.

Abstract: A method and apparatus for providing near real-time fault detection in a manufacturing process is provided. The apparatus includes a processing tool adapted to manufacture a processing piece and an interface, coupled to the processing tool, for receiving operational data from the processing tool related to the manufacture of the processing piece, and product data defining characteristics of the processing piece. In one embodiment, the processing tool is in the form of semiconductor fabrication equipment and the processing piece is a silicon wafer. A fault detection unit is provided to determine if a fault condition exists with the processing tool from the operational data or with the processing piece from the product data. An Advanced Process Control (APC) framework is further provided to receive the operational and product data from the first interface, and to send the data to the fault detection unit.

Abstract: The present invention provides for a method and an apparatus for implementing corrected species by monitoring state parameters in a manufacturing process. A process run of semiconductor devices is performed. Production data relating to the process run of semiconductor devices is acquired. The acquired production data is stored into a production database. A recipe management analysis is performed. The apparatus of the present invention comprises: a recipe management system; a first machine interface connected to said recipe management system; a processing tool connected to said first machine interface; and a fault detection system connected to said first machine interface.

Abstract: Reticles are selected for use in a wafer processing system based on the wafer-processing recipe and on the level of degradation exhibited by the reticle after multiple exposures to light and constant physical handling. In an example embodiment of an integrated reticle sorter and stocker, a scanner identifies the reticle and gathers dimensional data on each reticle. A sorter sorts reticles within reticle pods according to the processing recipe and stores the pods within a storage location in the stocker. A computer arrangement then records information from the scanner and the sorter and assesses whether any of the reticles has degraded beyond an acceptable level of usage.

Abstract: Systems and methods for managing automated material handling systems, such as semiconductor fabrication facilities, using material item (e.g., wafer lot) attributes and cassette attributes are provided. A semiconductor fabrication facility typically includes multiple wafer lots and multiple cassettes for storing the wafer lots. A system and method, in one embodiment of the invention, includes setting one or more lot attributes for each wafer lot, setting one or more cassette attributes for each cassette, and selecting a particular cassette for holding a particular wafer lot based on the one or more wafer lot attributes of the particular wafer lot and the one or more cassette attributes of the particular cassette. The wafer lot and cassette attributes may, for example, include an attribute identifying a position in a fabrication sequence and one or more attributes indicative of one or more contaminants.

Abstract: A wafer fabrication system is presented including a measurement system which screens measurement data prior to dissemination. The measurement system may include an equipment interface computer coupled between a measurement tool and a work-in-process (WIP) server. The measurement tool may perform one of possibly several measurement procedures (i.e., “recipes”) upon one or more semiconductor wafers processed as a lot, thereby producing measurement data. The WIP server may select the measurement recipe and store the measurement data. The equipment interface computer may receive the measurement data produced by the measurement tool and compare the measurement data to a predetermined range of acceptable values in order to determine if the measurement data is within the range of acceptable values. The equipment interface computer may display the measurement data upon a display device such that any portion of the measurement data not within the range of acceptable values is visually flagged (e.g.

Abstract: A method for aligning wafers includes defining a grid on a wafer; determining a grid offset parameter based on an offset between the grid and an external reference point defined on the wafer; and aligning the wafer based on the grid offset parameter and the external reference point. A system for aligning wafers includes a database server and a tool. The database server is adapted to store a grid offset parameter associated with a wafer. The grid offset parameter defines an offset between a grid defined on the wafer and an external reference point defined on the wafer. The tool is adapted to align the wafer based on the grid offset parameter associated with the wafer and the external reference point.

Abstract: A system for verifying the integrity of components moving within a material handling system ensures that only components of acceptable integrity and condition are allowed to move onto the processing locations of a semiconductor plant. In an example embodiment, components that are warped or cracked are initially detected and scanned by a beam break system and/or an optical system. An integrity verification assessment is made immediately on the component to determine whether the scanned component meets with a predefined baseline parameter or characteristic. The components that do not pass integrity verification are then removed from the material handling system while the components that pass move on to the first processing location.

Abstract: Techniques for controlling the flow of wafer lots in a semiconductor fabrication facility having multiple storage locations and a fabrication facility employing such techniques are provided. A process and system for controlling the flow of wafer lots within a semiconductor fabrication facility, in accordance with one embodiment of the invention, includes determining a first storage location for a wafer lot, determining, prior to moving the wafer lot, an availability condition of the first storage location based on a condition level of the first storage location and a priority of the wafer lot, and storing the wafer lot in the storage location if the location is available and storing the wafer lot in an alternate location if the storage location is unavailable. The storage location may, for example, be a stocker.

Abstract: A system and method for stocking and sorting reticles used in a semiconductor fabrication facility, the facility having a material handling system that presents a reticle to a photolithography process area. In an example embodiment of the reticle management system, a reticle storage system and a reticle sorting apparatus are coupled to a host system that is adapted to track and control the movement of reticles in the material handling system. The host system is capable of interfacing with a management input module that integrates management directives into the reticle flow plan in the manufacturing process. The result is a reticle management system that is flexible enough to manage a finite number of reticles and pods in minimizing the delivery time of a reticle to the desired location while responding to changing conditions external to the manufacturing process.

Abstract: An apparatus and a system for stocking and sorting wafers in a wafer processing system reduce cycle time in manufacturing and reduce excessive handling of delicate wafers. In an example embodiment, the apparatus includes in an enclosure having therein a scanner adapted to identify codes located on the wafer carriers that indicate the position of a wafer within the carrier. A sorting mechanism for sorting wafers and carriers within the enclosure is also included as well as a computer arrangement that communicates with the management system of the wafer processing system. One of the advantages of the present invention is the reduction in cycle time that is achieved by sorting wafers immediately on demand while at a stocking location.

Abstract: A computer controlled manufacturing arrangement and method for selecting between multiple paths for transporting cassettes between processing locations. The manufacturing arrangement includes a plurality of stockers interconnected with tracks on which cassettes are carried on vehicles. A first and second stocker are interconnected by at least a first path and a second path formed by the tracks, and a cassette can be transported from the first to the second stocker via either of the two paths. A plurality of robotic arrangements are configured to transfer cassettes between the stockers and the vehicles. A data processing system is coupled to the robotic arrangements and configured and arranged to maintain an historical record of codes indicative of periods of time expended in transporting cassettes from the first stocker to the second stocker via the first path and second path, respectively.

Abstract: Methods and systems for managing test wafers an automated material handling system are provided. Test material is classified into a plurality of classes. A time profile for each class of test material for a time period is determined and the test material is placed into cassettes based on the determined time profile for each class. When a request to pick up a particular group of a test material class is received, a cassette is identifying for picking up the particular group based on the contents of the cassette.

Abstract: The present invention provides for a method and an apparatus for implementing an embedded process control into a manufacturing tool system. At least one semiconductor device is processed. An embedded process control procedure is performed in response to the processing of the semiconductor device. A subsequent process of semiconductor device is performed in response to the embedded process control procedure. The apparatus of the present invention comprises: a computer system; and at least one manufacturing tool system interfaced with the computer, the manufacturing tool system comprising an embedded process control system capable of receiving commands from the computer system and control a manufacturing process performed by the manufacturing tool system.

Abstract: An automated material handling system is presented for a manufacturing facility divided into separate fabrication areas. The automated material handling system plans and carries out the movement of work pieces between fabrication areas and maintains a database indicating the location of each work piece within the manufacturing facility. In one embodiment, the automated material handling system accomplishes the containerless transfer of semiconductor wafers through a wall separating a first and second fabrication areas. The wafers are transported within containers (e.g., wafer boats). The material handling system includes a number of transfer tools, including air lock chambers, mass transfer systems, robotic arms, and stock areas. The material handling system also includes a control system which governs the operations of the transfer tools as well as the dispersal of containers.