An LED package includes N number of first pins, six second pins and N number of LED units, where N is four or six. Each of the LED units includes first to third LEDs, each of which has first and second terminals. The first terminal of the first LED for each of (2j1).sup.th and (2j).sup.th LED units is connected to a (2j1).sup.th first pin. The first terminals of the second and third LEDs for each of the (2j1).sup.th and (2j).sup.th LED units are connected to a (2j).sup.th first pin, where j is an integer and 0<jN/2. The second terminals of the first, second and third LEDs for the (2j1).sup.th LED unit are connected to the 1.sup.st, 2.sup.nd and 3.sup.rd second pins, respectively. The second terminals of the first, second and third LEDs for the (2j).sup.th LED unit are connected to the 4.sup.th, 5.sup.th and 6.sup.th second pins.

An illumination device includes a light guide member having a bar-like shape and a light source disposed so as to face an end surface of the light guide member. The illumination device guides light from the light source in the light guide member and emits the light from a light emission surface of the light guide member formed in a longitudinal direction of the light guide member. The light emission surface includes a first light diffusing portion that is formed in a first portion near the light source and that has a protruding/recessed shape, and a second light diffusing portion that is formed in a second portion adjacent to an end of the first light diffusing portion, the end being away from the light source. The second light diffusing portion has a protruding/recessed shape and has lower light diffusivity than the first light diffusing portion.

An illumination device includes a light guide member having a bar-like shape and a light source disposed so as to face an end surface of the light guide member. The illumination device guides light from the light source in the light guide member and emits the light from a light emission surface of the light guide member formed in a longitudinal direction of the light guide member. The light emission surface includes a first light diffusing portion that is formed in a first portion near the light source and that has a protruding/recessed shape, and a second light diffusing portion that is formed in a second portion adjacent to an end of the first light diffusing portion, the end being away from the light source. The second light diffusing portion has a protruding/recessed shape and has lower light diffusivity than the first light diffusing portion.

An LED package includes N number of first pins, six second pins and N number of LED units, where N is four or six. Each of the LED units includes first to third LEDs, each of which has first and second terminals. The first terminal of the first LED for each of (2j1).sup.th and (2j).sup.th LED units is connected to a (2j1).sup.th first pin. The first terminals of the second and third LEDs for each of the (2j1).sup.th and (2j).sup.th LED units are connected to a (2j).sup.th first pin, where j is an integer and 0<jN/2. The second terminals of the first, second and third LEDs for the (2j1).sup.th LED unit are connected to the 1.sup.st, 2.sup.nd and 3.sup.rd second pins, respectively. The second terminals of the first, second and third LEDs for the (2j).sup.th LED unit are connected to the 4.sup.th, 5.sup.th and 6.sup.th second pins.

An imaging apparatus comprising a chassis, a light source for directing light along a first optical axis segment of the light path, at least a first fold mirror supported within the light path for redirecting light along a second optical axis segment, the at least a first fold mirror having a top edge, a first elongated lead member supported by the chassis, the first elongated lead member forming at least a first substantially straight surface that extends substantially parallel to the second optical axis segment, a first drive mechanism supported by the chassis and extending alongside and spaced apart from the first lead member, an area sensor aligned for movement with a segment of the light path, wherein the first lead member and the first drive mechanism are located to first and second different sides of the second optical axis segment and wherein each of the first lead member and the first drive mechanism are located at a height below the top edge of the at least a first fold mirror.

In order to make it possible to image the surface of a workpiece from a plurality of directions without reducing the amount of light to be projected to the workpiece, a light projection device having light emitting surfaces opposite to the workpiece and formed with a slit allowing light reflected by the workpiece to pass from the light emitting surface side toward an opposite side thereof is adapted such that the slit is formed in a tapered shape whose width gradually increases from the light emitting surface side toward the opposite side.

Improved wafer-scale testing of optoelectronic devices, such as CMOS image scan devices, is provided. A probe card includes an LED light source corresponding to each device under test in the wafer. The LED light sources provide light from a phosphor illuminated by the LED. A pinhole and lens arrangement is used to collimate the light provided to the devices under test. Uniformity of illumination can be provided by closed loop control of the LED light sources using internal optical signals as feedback signals, in combination with calibration data relating the optical signal values to emitted optical intensity. Uniformity of illumination can be further improved by providing a neutral density filter for each LED light source to improve uniformity from one source to another and/or to improve uniformity of the radiation pattern from each LED light source.

An illumination device includes a light guide member having a bar-like shape and a light source disposed so as to face an end surface of the light guide member. The illumination device guides light from the light source in the light guide member and emits the light from a light emission surface of the light guide member formed in a longitudinal direction of the light guide member. The light emission surface includes a first light diffusing portion that is formed in a first portion near the light source and that has a protruding/recessed shape, and a second light diffusing portion that is formed in a second portion adjacent to an end of the first light diffusing portion, the end being away from the light source. The second light diffusing portion has a protruding/recessed shape and has lower light diffusivity than the first light diffusing portion.

An image reading device includes a transparent member, a reading unit, and a sheet member provided on an upstream side, in a sheet conveyance direction, of the transparent member with respect to the reading position. The reading unit reads an image on a conveyed sheet via a reading position of the transparent member. The sheet member guides the conveyed sheet. The sheet member includes, in a sheet conveyance area in a sheet width direction orthogonal to the sheet conveyance direction, a first area where a leading edge of the conveyed sheet and the sheet member contact each other and a second area where the leading edge of the conveyed sheet and the sheet member do not contact each other.

An image forming apparatus comprises an automatic document feeder (ADF); a light source configured to irradiate the document conveyed by the ADF with light; a glass member which can be switched to a first mode in which the light from the light source is transmitted and to a second mode in which the light from the light source is reflected; a signal processing circuit configured to include an image sensor for respectively receiving the reflected light of the document and the glass member, read an image of the document in the first mode and generate a signal of a white reference value based on the reflected light of the glass member in the second mode; and a shading correction circuit configured to correct, based on the signal of the white reference value, image data of the document read such that the brightness in the horizontal scanning direction is uniform.