A compressing apparatus has a compressing jig and a pressing device. The compressing jig has a lower compressing assembly and an upper compressing assembly. The lower compressing assembly has a lower mount with at least one pitching plate and at least one limiting set. Each one of the at least one limiting set has multiple poles disposed around a corresponding pitching plate. Each one of the multiple poles has a top end higher than the corresponding pitching plate and a limiting indention disposed at the top end with a supporting portion disposed at a same height with the corresponding pitching plate. The upper compressing assembly has at least one clamping plate respectively aligned with the at least one pitching plate and being movable up and down. The pressing device has a base with a receiving space to receive the upper compressing assembly.

An on-wafer calibration device comprises on a substrate at least a first measuring port, at least a first switch element, at least two calibration standards, and a controller unit or a control interface for control of the first switch element. The first switch element is controlled in a manner that it selectively connects a wafer probe tip connectable to the first measuring port to the at least two calibration standards.

A method of operating a processing apparatus is provided. The method includes placing a substrate storage container on a load port. The method includes matching a plurality of positioning holes are on a base board of the substrate storage container with a plurality of positioning pins on a base frame of the load port. The method also includes transferring a substrate from the substrate storage container when the substrate storage container is placed on the base frame.

A system includes a factory interface, a load port connected to the factory interface, and a system controller. The system controller is to, responsive to detecting that a container is received at the load port, determine a type of parts for storage at the container. One or more mapping patterns associated with the determined type of parts is identified. A detection system of robot arm(s) of the factory interface is moved according to the identified mapping pattern(s) to detect one or more parts stored by the container. A mapping of the container is determined based on the movement of the robot arm(s). The mapping indicates regions of the container that stores detected parts and a position of each of the detected parts. Based on the mapping, the robot arm(s) either remove a detected part form the container or place an additional part in the container.

A method and apparatus for soldering a chip (1a) to a substrate (3). A chip carrier (8) is provided between a flash lamp (5) and the substrate (3). The chip (1a) is attached to the chip carrier (8) on a side of the chip carrier (8) facing the substrate (3). A solder material (2) is disposed between the chip (1a) and the substrate (3). The flash lamp (5) generates a light pulse (6) for heating the chip (1a). The heating of the chip (1a) causes the chip (1a) to be released from the chip carrier (8) towards the substrate (3). The solder material (2) is at least partially melted by contact with the heated chip (1a) for attaching the chip (1a) to the substrate (3).

A method includes identifying a wafer position for a plurality of die on a wafer, storing the wafer position for each of the plurality of die in a database, dicing the wafer into a plurality of singulated die, positioning each of the singulated die in a die position location on a tray, and storing the die position on the tray for each of the singulated die in the database. The database includes information including the wafer position associated with each die position. The tray is transported to a processing tool, and at least one of the plurality of singulated die is removed from the die position on the tray and processed in the processing tool. The processed singulated die is replaced in the same defined location on the tray that the singulated die was positioned in prior to the processing. Other embodiments are described and claimed.

An electronic component transport apparatus includes: an openable and closable first opening and closing portion; a first rotation support portion which supports the first opening and closing portion to be rotatable; a second opening and closing portion provided to be openable and closable in the first opening and closing portion; and a second rotation support portion which supports the second opening and closing portion to be rotatable. An area of the first opening and closing portion is greater than an area of the second opening and closing portion.

An article transport device includes an article support member for supporting an article having a plate-shaped flange portion in an upper portion thereof, with the article placed on its receiving member. The article support member further includes a restricting member which is positioned such that at least a portion of the restricting member is located across from at least a portion of a front side surface of the flange portion when the article is in the supported state, and which is configured to restrict the article in the supported state from moving at least in the front direction by distances greater than a movement distance specified in advance. The restricting member includes a pair of front restricting portions that are so located to be spaced apart from each other to form a gap, wherein the restricting member and the receiving member are fixedly connected to each other.

A cover tape for packing an electronic component includes: a substrate layer; a heat sealing layer placed on one surface side of the substrate layer; and an intermediate layer placed between the substrate layer and the heat sealing layer, and a transmitted image definition based on JIS K 7374, with an optical comb width set to 0.5 mm, is 30% or more.

A module tray for a semiconductor device includes a base plate, first and second sidewalls extending in a vertical direction from opposite sides of the base plate to define an accommodation space, a dividing wall extending in the vertical direction from the base plate between the first and second sidewalls, first to fourth fastening guides with first to fourth fastening grooves, respectively, on inner surfaces of the first and second sidewalls and opposite side surfaces of the dividing wall, and first to fourth guide grooves on the inner surfaces of the first and second sidewalls and the opposite side surfaces of the dividing wall, respectively, the first to fourth guide grooves having curved concave shapes, and an upper end portion of each of the first to fourth fastening grooves gradually widening toward a top thereof.