JP4151565B2 - Tape carrier - Google Patents

Description

  The present invention relates to a tape carrier, and is particularly suitable when applied to a method of arranging pad electrodes on both sides of a tape carrier.

In a conventional semiconductor package, there is a method in which a test pad for inspecting an electrical characteristic of an IC is formed only on one side of a tape carrier, and the electrical characteristic is inspected only from that side.
On the other hand, for example, Patent Document 1 discloses a method in which patterned metal layers are formed on both surfaces of a tape carrier and the metal patterns on both surfaces are connected to each other through via holes.
Japanese Patent Laid-Open No. 5-160209

However, in the method of forming the test pad only on one side, the layout area of the test pad is limited. For this reason, in order to be able to cope with multi-pin measurement, it is necessary to reduce the area of the test pad, and there is a problem that high accuracy is required for alignment.
On the other hand, when the area of the test pad is increased in order to ease the alignment accuracy, there is a problem that the number of test pads that can be arranged is reduced and it is not possible to cope with multi-pin measurement.

In the method disclosed in Patent Document 1, inner leads, outer leads, and test pads are arranged on the surface of the tape carrier, and a ground layer or a power supply layer is arranged on the back surface of the tape carrier. For this reason, there is a problem that the test pad is disposed only on one side of the tape carrier, and the layout area of the test pad cannot be increased.
Accordingly, an object of the present invention is to provide a tape carrier capable of increasing the layout area of a test pad.

According to the tape carrier of one aspect of the present invention, the tape carrier, the first wiring group and the second wiring group formed on the first surface of the tape substrate, and the first surface are formed on the first surface. A plurality of first test pads connected to the first wiring group, a plurality of second test pads formed on a second surface opposite to the first surface of the tape substrate, and the tape A via embedded in the substrate and connecting the second wiring group and the plurality of second test pads, wherein the plurality of first test pads and the plurality of second test pads are connected to the tape substrate. It is a different arrangement when seen through,
The interval between the plurality of first test pads is equal to the interval between the second test pads, and the first test pad in the first stage closest to the one end of the tape substrate and the plurality of first test pads. And the distance between the other end of the tape substrate and the second test pad that is closest to the other end of the plurality of second test pads is equal,
When the second surface is viewed in an inverted manner, the plurality of second test pads are arranged in alignment with the plurality of first test pads on the first surface .

As a result, the second test pad formed on the back surface of the tape substrate can be connected to the second wiring layer formed on the front surface of the tape substrate, and the test pad can be mounted without changing the position of the inner lead. Can be placed on both sides.

Furthermore, the number of test pads that can be arranged on the tape substrate can be increased without reducing the area of the test pads.
Also, the arrangement of the plurality of first test pads on the first surface and the arrangement of the plurality of second test pads on the second surface are arranged so that the arrangement when the tape substrate is viewed upside down coincides. It is characterized by.

Accordingly, the first test pad and the second test pad can be probed without changing the measurement jig, and the electrical characteristic inspection can be efficiently performed while supporting multi-pin measurement.

  Furthermore, if the same input terminals are provided on both sides of the tape substrate, even if test pads are provided on both sides of the tape substrate, it is possible to input signals from only one side of the tape substrate, and electrical characteristic inspection can be performed. It can be done efficiently.

Further, according to the tape carrier of one aspect of the present invention, the first test pad and the front
The second test pad includes a power supply terminal.

  This makes it possible to match the positions of the power supply terminals when the tape substrate is reversed. For this reason, even when test pads are provided on both sides of the tape substrate, it is possible to supply the power supply voltage from the same side without changing the measuring jig, and the electrical characteristic inspection can be performed efficiently. it can.

Hereinafter, a tape carrier according to an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is a perspective view showing a schematic configuration of the tape carrier according to the first embodiment of the present invention.
In FIG. 1, on both sides of the tape substrate 1, sprocket holes 2 for transporting the tape substrate 1 are provided at predetermined intervals. In addition, as a material of the tape board | substrate 1, a polyimide resin or PET (polyethylene terephthalate) resin etc. can be used, for example.

Wirings 3 a and 3 b and a test pad 4 a are formed on the tape substrate 1, and a test pad 4 b is formed on the back surface of the tape substrate 1. As the wirings 3a and 3b, inner leads or outer leads can be formed. Here, the test pad 4a formed on the tape substrate 1 is connected to the wiring 3a.
A via 3c is embedded in the tape substrate 1, and a test pad 4b formed on the back surface of the tape substrate 1 is connected to the wiring 3b through the via 3c.

  Here, by arranging the test pads 4a and 4b on both sides, it is possible to increase the arrangement area of the test pads 4a and 4b compared to the case where the test pads a and 4b are arranged on only one side. For this reason, the number of test pads 4a and 4b that can be arranged on the tape substrate 1 can be increased without reducing the area of the test pads 4a and 4b, and the multi-pin measurement can be handled while relaxing the alignment accuracy. be able to.

Further, the test pad 4a and the test pad 4b can be arranged so that at least some of the regions overlap each other. Thereby, the distances L1 and L2 between the test pads 4a and 4b can be narrowed, respectively, and the number of test pads that can be arranged can be increased without reducing the area of the test pads.
Further, the test pads 4a and 4b can be arranged so that the arrangement when the tape substrate 1 is inverted is matched. That is, the distance L1 between the test pads 4a and the distance L2 between the test pads 4b are made equal, the distance L3 between one end of the tape substrate 1 and the test pad 4a closest thereto, and the other end of the tape substrate 1 and The distance L4 between the test pad 4b and the nearest test pad 4b can be made equal. Accordingly, the test pads 4a and 4b can be probed without changing the measurement jig, and the electrical characteristic inspection can be efficiently performed while supporting multi-pin measurement.

FIG. 2 is a perspective view showing a schematic configuration of a tape carrier according to the second embodiment of the present invention.
In FIG. 2, sprocket holes 12 for conveying the tape substrate 11 are provided at predetermined intervals on both sides of the tape substrate 11. Wirings 13 a to 13 d and test pads 14 a to 14 d are formed on the tape substrate 11, and test pads 14 a ′ to 14 d ′ are formed on the back surface of the tape substrate 11. As the wirings 13a to 13d, inner leads or outer leads can be formed. Here, the test pads 14a to 14d formed on the tape substrate 11 are connected to the wirings 13a to 13d, respectively.

Also, vias 13a 'to 13d' are embedded in the tape substrate 11, and test pads 14a 'to 14d' formed on the back surface of the tape substrate 11 are connected to the wirings 13a to 13d through the vias 13a 'to 13d', respectively. Each is connected.
Here, by arranging the test pads 14 a to 14 d and 14 a ′ to 14 d ′ on both surfaces, the same input terminal can be provided on both sides of the tape substrate 11. For this reason, even when the test pads 14a to 14d and 14a 'to 14d' are provided on both surfaces of the tape substrate 11, it becomes possible to input signals from only one surface of the tape substrate 11, and the electrical characteristic inspection is efficiently performed. It can be carried out.

  Further, the test pads 14a to 14d and the test pads 14a 'to 14d' can be arranged so as to overlap each other. Accordingly, the test pads 14a to 14d and the test pads 14a 'to 14d' can be made to coincide with each other when the tape substrate 11 is inverted, and the intervals between the test pads 14a to 14d and 14a 'to 14d' can be matched. The number of test pads 14a to 14d and 14a 'to 14d that can be arranged can be increased.

The test pads 14a to 14d and 14a 'to 14d can be arranged so that the power supply terminals are symmetrical with respect to the center line C. That is, for example, if the test pads 14a and 14a ′ and the test pads 14d and 14d ′ are V _EE terminals and the test pads 14b and 14b ′ and the test pads 14c and 14c ′ are V _CC terminals, the test pads 14b and 14b ′ The distance L11 between the center line C and the distance L12 between the test pads 14c, 14c ′ and the center line C are made equal, and the distance L13 between the test pads 14a, 14a ′ and the center line C and the test pad The distance L14 between 14d and 14d 'and the center line C can be made equal.

  This makes it possible to match the positions of the power supply terminals when the tape substrate 11 is reversed. For this reason, even when the test pads 14a to 14d and 14a 'to 14d are provided on both surfaces of the tape substrate 11, the supply of the power supply voltage and the characteristic inspection can be performed from the same surface side without changing the measuring jig. Thus, the electrical characteristic inspection can be performed efficiently.

It is a perspective view showing a schematic structure of a tape carrier concerning a 1st embodiment of the present invention. It is a perspective view which shows schematic structure of the tape carrier which concerns on 2nd Embodiment of this invention.

Explanation of symbols

  1,11 Tape substrate, 2,12 Sprocket hole, 3a, 3b, 13a-13d Wiring, 3c, 13a'-13d 'Via, 4a, 4b, 14a-14d, 14a'-14d' Test pad

Claims (2)

A tape substrate;
A first wiring group and a second wiring group formed on the first surface of the tape substrate;
A plurality of first test pads formed on the first surface and connected to the first wiring group ;
A plurality of second test pads formed on a second surface opposite to the first surface of the tape substrate;
Vias embedded in the tape substrate and connecting the second wiring group and the plurality of second test pads;
With
The plurality of first test pads and the plurality of second test pads are arranged differently when seen through the tape substrate,
An interval between the plurality of first test pads is equal to an interval between the second test pads,
The distance between one end of the tape substrate and the first test pad closest to the one end among the plurality of first test pads, the other end of the tape substrate and the plurality of second test pads The distance from the second test pad closest to the other end is the same,
The tape carrier characterized in that the arrangement of the plurality of second test pads coincides with the arrangement of the plurality of first test pads on the first surface when the second surface is reversed. . The tape carrier according to claim 1 , wherein the plurality of first and second test pads include a power supply terminal.

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