Abstract: A substrate processing apparatus includes: a load port into and out of which the transport container is carried; and an apparatus controller that controls operations in the load port. The apparatus controller includes a storage unit that stores transition data of parameter values sent from outside based on a transport container identification code. The transition data of the parameter values each comprises a usage count of the transport container and a corresponding parameter value that quantifies a result of at least one of an operation performed to remove the lid after the transport container is carried into the load port and an operation performed to carry the container out of the load port.

Abstract: A substrate processing apparatus includes plural heating modules each including a table on which a substrate is placed to be heated, the substrate having plural heated zones. The table has plural heaters each assigned to heat respective ones of the heated zones. Heat generation of the heaters is controlled independently. A control unit controls the heaters such that integrated quantities of heat of the respective heated zones given by the corresponding heaters from first to second time point are substantially identical to each other in each of the heating modules, and are substantially identical to each other among the heating modules. The first time point is set when a temperature transition profile of the substrate is rising toward a process temperature after placing the substrate on the table under a condition where heat generation of the heaters is stable. The second time point is set after the temperature transition profile reaches the process temperature.

Abstract: An interface station of a coating and developing treatment system has: a cleaning unit cleaning at least a rear surface of a wafer before the wafer is transferred into an exposure apparatus; an inspection unit inspecting the rear surface of the cleaned wafer whether the wafer is exposable, before it is transferred into the exposure apparatus; wafer transfer mechanisms including arms transferring the wafer between the units and a wafer transfer control part controlling operations of the wafer transfer mechanisms. When it is determined that a state of the wafer becomes an exposable state by re-cleaning in the cleaning unit as a result of the inspection, the wafer transfer control part controls the wafer transfer mechanisms to transfer the wafer again to the cleaning unit.

Abstract: An interface station of a coating and developing treatment system has: a cleaning unit cleaning at least a rear surface of a wafer before the wafer is transferred into an exposure apparatus; an inspection unit inspecting the rear surface of the cleaned wafer whether the wafer is exposable, before it is transferred into the exposure apparatus; wafer transfer mechanisms including arms transferring the wafer between the units and a wafer transfer control part controlling operations of the wafer transfer mechanisms. When it is determined that a state of the wafer becomes an exposable state by re-cleaning in the cleaning unit as a result of the inspection, the wafer transfer control part controls the wafer transfer mechanisms to transfer the wafer again to the cleaning unit.

Abstract: An interface station of a coating and developing treatment system has: a cleaning unit cleaning at least a rear surface of a wafer before the wafer is transferred into an exposure apparatus; an inspection unit inspecting the rear surface of the cleaned wafer whether the wafer is exposable, before it is transferred into the exposure apparatus; wafer transfer mechanisms including arms transferring the wafer between the units and a wafer transfer control part controlling operations of the wafer transfer mechanisms. When it is determined that a state of the wafer becomes an exposable state by re-cleaning in the cleaning unit as a result of the inspection, the wafer transfer control part controls the wafer transfer mechanisms to transfer the wafer again to the cleaning unit.

Abstract: In one embodiment, a coating and developing apparatus is provided with transfer units, provided between a stack of early-stage processing unit blocks and a stack of later-stage processing unit blocks to transfer a substrate between the transport mechanisms of laterally-adjacent unit blocks, and a vertically-movable auxiliary transfer mechanism for transporting a substrate between the transfer units. A stack of first developing unit blocks is stacked on the stack of early-stage processing unit blocks, and a stack of second developing unit blocks is stacked on the stack of later-stage processing unit blocks.

Abstract: In one embodiment, a coating and developing apparatus includes a processing block having two early-stage coating unit blocks, two later-stage coating unit blocks and two developing unit blocks, each unit blocks being vertically stacked on each other, The apparatus has at least two operation modes M1 and M2 adapted for abnormality. In mode M1 the processing module that processed the abnormal substrate in the developing unit blocks is identified, and subsequent substrates are transported to the processing module or modules, of the same type as the identified processing module, other than the identified processing module. In mode M2, the developing unit block that processed the abnormal substrate is identified, and subsequent substrates are transported to the developing unit block other than the identified developing unit block.

Abstract: A substrate processing apparatus includes: a load port into and out of which the transport container is carried; and an apparatus controller that controls operations in the load port. The apparatus controller includes a storage unit that stores transition data of parameter values sent from outside based on a transport container identification code. The transition data of the parameter values each comprises a usage count of the transport container and a corresponding parameter value that quantifies a result of at least one of an operation performed to remove the lid after the transport container is carried into the load port and an operation performed to carry the container out of the load port.

Abstract: A substrate holder positioning method, capable of positioning a substrate holder without using any positioning jig, includes: measuring a first position of a substrate held on a substrate holder included in a substrate carrying mechanism; carrying the substrate held on the substrate holder to a substrate rotating unit for holding and rotating the substrate; turning the substrate held by the substrate rotating unit through a predetermined angle by the substrate rotating unit; transferring the substrate turned by the substrate rotating unit from the substrate rotating unit to the substrate holder; measuring a second position of the substrate transferred from the substrate rotating unit to the substrate holder; determining the position of the center of rotation of the substrate rotating unit on the basis of the first and the second position; and positioning the substrate holder on the basis of the position of the center of rotation.

Abstract: In a coating and developing treatment system including a treatment station and an interface station, the interface station has: a cleaning unit cleaning a rear surface of a wafer before the wafer is transferred into an exposure apparatus; an inspection unit inspecting whether the cleaned wafer is in an exposable state; and a wafer transfer mechanism including an arm transferring the wafer between the cleaning unit and the inspection unit. Each of the cleaning unit and the inspection unit is provided at multiple tiers in an up and down direction on the front side in the interface station, and the wafer transfer mechanism is provided in a region adjacent to the cleaning units and the inspection units.

Abstract: In one embodiment, a coating and developing apparatus includes a processing block having two early-stage coating unit blocks, two later-stage coating unit blocks and two developing unit blocks, each unit blocks being vertically stacked on each other, The apparatus has at least two operation modes M1 and M2 adapted for abnormality. In mode M1 the processing module that processed the abnormal substrate in the developing unit blocks is identified, and subsequent substrates are transported to the processing module or modules, of the same type as the identified processing module, other than the identified processing module. In mode M2, the developing unit block that processed the abnormal substrate is identified, and subsequent substrates are transported to the developing unit block other than the identified developing unit block.

Abstract: A substrate treatment system comprise a treatment station having a plurality of treatment units provided at multiple tiers in an up-down direction, a cassette mounting table on which a cassette housing a plurality of wafers W is mounted, and a wafer transfer mechanism arranged between the treatment station and the cassette mounting table, wherein a delivery block in which a plurality of delivery units are provided at multiple tiers is provided between the treatment station and the wafer transfer mechanism, the delivery units temporarily housing a wafer to be transferred between the cassette mounting table and the treatment station and a wafer to be transferred between the tiers of the treatment units. The wafer transfer mechanism includes a first transfer arm that transfers a wafer between the cassette mounting table and the delivery block, and a second transfer arm that transfers a wafer between the tiers of the delivery units.

Abstract: Disclosed is an inspection device for inspecting deformation of a substrate holding member of a substrate transport apparatus. The substrate holding member is moved in the forward-and-backward direction relative to the transport base to pass across a light path of the detection light formed by an optical detection unit. The position, with respect to a direction transverse to the forward-and-backward direction, of the substrate holding member is detected based on a detection signal of the optical detection unit. Based on a correlation data expressing the relationship between a first parameter indicative of a change of a position of the substrate holding member with respect to the forward-and-backward direction and a second parameter indicative of the change of the position of the substrate holding member with respect to the direction transverse to the forward-and-backward direction, whether or not deformation occurs in the substrate holding member is judged.

Abstract: A substrate processing apparatus includes: a carrier block including first and second carrier placement units spaced apart in a right and left direction; a processing block having a layered structure in which a plurality of layered parts are vertically arranged, the layered parts each including a substrate transport mechanism for transporting a substrate and a processing module for processing a substrate; a tower unit including plural substrate placement units located at height positions where a substrate is transferred by the substrate transport mechanism of the layered part corresponding to the substrate placement unit; a first substrate transfer mechanism configured to transfer a substrate between the carrier on the first carrier placement unit and the substrate placement unit of the tower unit; and a second substrate transfer mechanism configured to transfer a substrate between the carrier on the second substrate placement unit and the substrate placement unit of the tower unit.

Abstract: In one embodiment, a coating and developing apparatus includes a processing block having two early-stage coating unit blocks, two later-stage coating unit blocks and two developing unit blocks, each unit blocks being vertically stacked on each other. The apparatus has at least two operation modes M1 and M2 adapted for abnormality. In mode M1 the processing module that processed the abnormal substrate in the developing unit blocks is identified, and subsequent substrates are transported to the processing module or modules, of the same type as the identified processing module, other than the identified processing module. In mode M2, the developing unit block that processed the abnormal substrate is identified, and subsequent substrates are transported to the developing unit block other than the identified developing unit block.

Abstract: In one embodiment, a coating and developing apparatus includes a processing block including a vertical stack of early-stage processing unit blocks; a vertical stack of later-stage processing unit blocks disposed laterally adjacent to respective ones of the early-stage processing unit blocks; a vertical stack of developing unit blocks stacked on the early-stage processing unit blocks; a vertical stack of auxiliary processing unit blocks disposed laterally adjacent to respective ones of the developing unit blocks; first transfer units, each of which are disposed between the laterally adjacent early-stage processing unit and later-stage processing unit; second transfer units, each of which is disposed between the laterally adjacent developing unit block and auxiliary processing unit block; and a auxiliary transfer mechanism for transferring a substrate between the first transfer units and between the second transfer units.

Abstract: In one embodiment, a coating and developing apparatus is provided with transfer units, provided between a stack of early-stage processing unit blocks and a stack of later-stage processing unit blocks to transfer a substrate between the transport mechanisms of laterally-adjacent unit blocks, and a vertically-movable auxiliary transfer mechanism for transporting a substrate between the transfer units. A stack of first developing unit blocks is stacked on the stack of early-stage processing unit blocks, and a stack of second developing unit blocks is stacked on the stack of later-stage processing unit blocks.

Abstract: In one embodiment, a coating and developing apparatus is provided with transfer units, provided between a stack of early-stage processing unit blocks and a stack of later-stage processing unit blocks to transfer a substrate between the transport mechanisms of laterally-adjacent unit blocks, and a vertically-movable auxiliary transfer mechanism for transporting a substrate between the transfer units. A stack of first developing unit blocks is stacked on the stack of early-stage processing unit blocks, and a stack of second developing unit blocks is stacked on the stack of later-stage processing unit blocks.

Abstract: A substrate holder positioning method, capable of positioning a substrate holder without using any positioning jig, includes: measuring a first position of a substrate held on a substrate holder included in a substrate carrying mechanism; carrying the substrate held on the substrate holder to a substrate rotating unit for holding and rotating the substrate; turning the substrate held by the substrate rotating unit through a predetermined angle by the substrate rotating unit; transferring the substrate turned by the substrate rotating unit from the substrate rotating unit to the substrate holder; measuring a second position of the substrate transferred from the substrate rotating unit to the substrate holder; determining the position of the center of rotation of the substrate rotating unit on the basis of the first and the second position; and positioning the substrate holder on the basis of the position of the center of rotation.

Abstract: A substrate holder positioning method, capable of positioning a substrate holder without using any positioning jig, includes: measuring a first position of a substrate held on a substrate holder included in a substrate carrying mechanism; carrying the substrate held on the substrate holder to a substrate rotating unit for holding and rotating the substrate; turning the substrate held by the substrate rotating unit through a predetermined angle by the substrate rotating unit; transferring the substrate turned by the substrate rotating unit from the substrate rotating unit to the substrate holder; measuring a second position of the substrate transferred from the substrate rotating unit to the substrate holder; determining the position of the center of rotation of the substrate rotating unit on the basis of the first and the second position; and positioning the substrate holder on the basis of the position of the center of rotation.