A method and apparatus for forming an optical stack having uniform and accurate layers is provided. A processing tool used to form the optical stack comprises, within an enclosed environment, a first transfer chamber, an on-board metrology unit, and a second transfer chamber. A first plurality of processing chambers is coupled to the first transfer chamber or the second transfer chamber. The on-board metrology unit is disposed between the first transfer chamber and the second transfer chamber. The on-board metrology unit is configured to measure one or more optical properties of the individual layers of the optical stack without exposing the layers to an ambient environment.

Described herein are methods and systems for chamber matching in a manufacturing facility. A method may include receiving a first chamber recipe advice for a first chamber and a second chamber recipe advice for a second chamber. The chamber recipe advices describe a set of tunable inputs and a set of outputs for a process. The method may further include adjusting at least one of the set of first chamber input parameters or the set of second chamber input parameters and at least one of the set of first chamber output parameters or the set of second chamber output parameters to substantially match the first and second chamber recipe advices.

This method includes: a step of imaging, by an imaging apparatus in a substrate treatment system, a reference substrate which is a reference for condition setting and acquiring a captured image of the reference substrate; a step of imaging, by the imaging apparatus, a treated substrate on which the predetermined treatment has been performed under a current treatment condition and acquiring a captured image of the treated substrate; a step of calculating a deviation amount in color information between the captured image of the treated substrate and the captured image of the reference substrate; a step of calculating a correction amount of the treatment condition based on a correlation model acquired in advance and on the deviation amount in the color information; and a step of setting the treatment condition based on the correction amount, wherein steps other than the step of acquiring a captured image of the reference substrate are performed for each of the treatment apparatuses.

A transfer method transfers a substrate between a transfer unit configured to hold and transfer the substrate and a substrate stage serving as a transfer destination or a transfer source of the substrate. The transfer method includes: acquiring positional information of the transfer unit and positional information of the substrate stage; determining whether or not there is a risk for the substrate to contact with the substrate stage, based on the acquired positional information of the transfer unit and positional information of the substrate stage; and when determined that there is a risk for the substrate to contact with the substrate stage, notifying the risk according to the determination at the determining.

There is provided a system that includes a review tool configured to review at least part of potential defects of an examined object, and assign each of the at least part of the potential defects with a multiplicity of attribute values. The system also includes a computer-based classifier configured to classify, based on the attribute values as assigned, the at least part of potential defects into a set of classes, the set comprising at least a first major class, a second major class and a first minor class, the classifier trained based on a training set comprising a multiplicity of training defects with assigned attribute values, the training defects classified into the set of classes.

A system includes an interface and a controller. The interface is configured to receive a state of a substrate processing tool comprising a plurality of process modules configured to process a substrate. The controller is configured to correlate the state with an input previously received by the substrate processing tool from the interface based on the state and to generate an output to control the substrate processing tool based on the correlation.

There is provided a substrate processing system, including: a plurality of substrate processing apparatuses; a first control part installed in each of the plurality of substrate processing apparatuses and configured to transmit a first apparatus data from each of the plurality of substrate processing apparatuses; a second control part configured to receive the first apparatus data from each of the plurality of substrate processing apparatuses, generate a priority data of each of the plurality of substrate processing apparatuses based on the first apparatus data, and transmit the priority data to the first control part; and a display part configured to display the priority data thereon.

A method and apparatus for forming an optical stack having uniform and accurate layers is provided. A processing tool used to form the optical stack comprises, within an enclosed environment, a first transfer chamber, an on-board metrology unit, and a second transfer chamber. A first plurality of processing chambers is coupled to the first transfer chamber or the second transfer chamber. The on-board metrology unit is disposed between the first transfer chamber and the second transfer chamber. The on-board metrology unit is configured to measure one or more optical properties of the individual layers of the optical stack without exposing the layers to an ambient environment.

A substrate processing apparatus includes a device management controller including a parts management control part configured to monitor the state of parts constituting the apparatus, a device state monitoring control part configured to monitor integrity of device data obtained from an operation state of the parts constituting the apparatus, and a data matching control part configured to monitor facility data provided from a factory facility to the apparatus. The device management controller is configured to derive information evaluating the operation state of the apparatus based on a plurality of monitoring result data selected from a group consisting of maintenance timing monitoring result data acquired by the parts management control part, device state monitoring result data acquired by the device state monitoring control part, and utility monitoring result data acquired by the data matching control part.

There is provided a substrate processing system, including: a plurality of substrate processing apparatuses; a first control part installed in each of the plurality of substrate processing apparatuses and configured to transmit a first apparatus data from each of the plurality of substrate processing apparatuses; a second control part configured to receive the first apparatus data from each of the plurality of substrate processing apparatuses, generate a priority data of each of the plurality of substrate processing apparatuses based on the first apparatus data, and transmit the priority data to the first control part; and a display part configured to display the priority data thereon.