KR20180045849A - Semiconductor device with multi-chip structure and semiconductor module using the same - Google Patents

Abstract

The present invention discloses a semiconductor device of a multi-chip structure and a semiconductor module using the same. Unit chips such as a source driver are formed in the semiconductor device in the multi-chip structure, thereby increasing a mounting density of the unit chips. Also, structures of input pads and output pads of the unit chips are the same or different, so that the mounting density can be increased by various options. The semiconductor device of a multi-chip structure comprises: a first unit chip in which first input pads and first output pads are formed; a second unit chip in which second input pads and second output pads are formed; and a scribe lane between the first unit chips and the second unit chips.

Description

TECHNICAL FIELD [0001] The present invention relates to a semiconductor device having a multi-chip structure and a semiconductor module using the same. [0002]

The present invention relates to a semiconductor device, and more particularly, to a semiconductor device having a multi-chip structure capable of improving the mounting density and a semiconductor module using the same.

The display device includes a display panel in which pixels are implemented by an OLED, an LED, or an LCD, drivers for driving pixels on the screen, and a timing controller for controlling operations of drivers. Generally, a driver can be divided into a source driver for providing a source driving signal corresponding to data to pixels of a display panel and a gate driver for providing a gate signal on a line-by-line basis of a screen.

Among them, a plurality of source drivers may be disposed on one side of the display panel according to the size and resolution of the screen.

Illustratively, in the case of a chip-on-glass (COG) scheme, the source driver is bonded onto the glass of the display panel.

In the case of the COG method, the source driver is made of a semiconductor chip by sawing a wafer, and is formed on the glass with the semiconductor chip itself without molding or encapsulation of an epoxy for packaging. Bonding.

In addition, the source driver may be mounted in various ways such as a chip-on-film (hereinafter referred to as " COF ") depending on the type of display panel.

When the display panel has a smaller screen area and higher resolution, the density of the source drivers disposed on one side of the display panel gradually increases.

In the case of the COG method, the source driver is bonded onto the glass using a bonding tool. The bonding tool has a plurality of bonding pads arranged in a line. The bonding tool picks up one source driver for each bonding pad, aligns the source drivers picked up on the bonding pads to a predetermined position of the glass, and closely bonds the source driver to the glass.

In the case of the COG method, the spacing distance between the mounted source drivers is determined by the spacing distance between the bonding pads of the bonding tool. Generally, the source driver is generally composed of individual packages, each of which has a rectangular shape and is divided into chip areas divided into scribe lanes of the wafer. The source drivers described above are arranged in a line in the major axis direction and then bonded to the glass.

In the case of bonding the individual source drivers as described above, the bonding tool requires an exemplary minimum spacing interval of 5,000 μm or more between the chips. Therefore, when bonding four source drivers with a long side length of 16,500um, the length for bonding the four source drivers is the sum of the lengths of the long sides of the four source drivers and the spacing distances of the three bonding pads (= 4 * 16,500um + 3 * 5,000um).

As described above, there is a limitation in improving the mounting density of the source drivers while meeting the chip-to-chip minimum spacing distance when bonding the individual source drivers while satisfying the chip-to-chip minimum spacing interval required by the bonding tool.

Source drivers are required to have improved wiring density as well as improved mounting density. In addition, the source driver is required to have various options for implementation.

It is an object of the present invention to provide a semiconductor device having a multi-chip structure and a semiconductor module using the same, in order to increase the mounting density of the unit chips such as the source driver.

Another object of the present invention is to provide a semiconductor device including two unit chips adjacent to each other around a scribe lane in one semiconductor substrate to increase the mounting density of the unit chips, and a semiconductor module using the same.

It is still another object of the present invention to provide a semiconductor device and a method of fabricating the same, or a method of manufacturing a semiconductor device, in which two identical unit chips are fabricated on one semiconductor substrate in a semiconductor process, A semiconductor device and a semiconductor module using the semiconductor device.

It is still another object of the present invention to provide a semiconductor module capable of improving the wiring density by forming wiring in multiple layers or sharing two wirings with respect to two unit chips formed in one semiconductor substrate.

It is still another object of the present invention to provide a semiconductor device of a multi-chip structure capable of increasing the mounting density with various options by having two unit chips formed on one semiconductor substrate have the same or different structure and a semiconductor module using the same have.

According to an aspect of the present invention, there is provided a semiconductor device having a multi-chip structure, including: a first unit chip having first input pads and first output pads; A second unit chip in which second input pads and second output pads are formed; And a scribe lane between the first unit chip and the second unit chip, wherein the first unit chip, the scribe lane, and the second unit chip have the same length as the length of the long side of the first unit chip And a semiconductor package extending in a direction perpendicular to the first direction.

A semiconductor module using a semiconductor device having a multi-chip structure according to the present invention includes: a semiconductor device having a rectangular shape and in which a first unit chip, a scribe lane, and a second unit chip are formed on the same semiconductor substrate in a longitudinal direction of a long side; An input line connecting the input terminals of the first end and the bonding region, an output connecting the output terminals of the second end opposite to the first end to the bonding region, The first input pads formed on the first unit chip and contacting the bonding region, and the second input pads formed on the second unit chip and contacting the bonding region are bonded to the bonding pad, The first output pads being formed in the first unit chip and in contact with the bonding region and the second output pads being formed in the second unit chip and being in contact with the bonding region, And the output pads are electrically connected to the ends of the output lines extending to the bonding region.

The present invention has the effect of increasing the mounting density of the unit chips by including the unit chip in a multi-chip structure in which two unit chips such as a source driver are formed on one semiconductor substrate.

In addition, the present invention has the effect of increasing the mounting density of the unit chips by manufacturing two identical unit chips in one semiconductor substrate in a semiconductor process and implementing the two unit chips connected by the scribe lane in a semiconductor package have.

Further, the present invention has the effect of improving the wiring density of the semiconductor module by sharing the wiring for two unit chips formed on one semiconductor substrate or by forming the wiring in multiple layers.

Further, since the two unit chips formed on one semiconductor substrate have the same or different structures, the present invention has the effect of increasing the mounting density of the unit chips with various options.

Further, the present invention has an effect of providing an advantage in designing an apparatus including a semiconductor device and a semiconductor module by improving the mounting density of the semiconductor device and the semiconductor module.

1 is a plan view showing a preferred embodiment of a semiconductor device of a multi-chip structure of the present invention.
2 is a plan view of a semiconductor substrate for explaining a manufacturing method of the semiconductor device of FIG.
3 is a plan view showing a preferred embodiment of a semiconductor module using the semiconductor device of FIG.
4 is a view for explaining a method of bonding a semiconductor device using a bonding tool;
5 is a plan view showing another embodiment of the semiconductor device of the multi-chip structure of the present invention.
Fig. 6 is a plan view showing a preferred embodiment of a semiconductor module using the semiconductor device of Fig. 5;
7 is a plan view showing still another embodiment of the semiconductor device of the multi-chip structure of the present invention.
8 is a cross-sectional view illustrating an output line connection state of the second unit chip CH2 of FIG. 7;
9 is a cross-sectional view illustrating an output line connection state of the first unit chip CH1 of FIG. 7;
10 is a plan view showing still another embodiment of the semiconductor device of the multi-chip structure of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. It is to be understood that the terminology used herein is for the purpose of description and should not be interpreted as limiting the scope of the present invention.

The embodiments described in the present specification and the configurations shown in the drawings are preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and thus various equivalents and modifications Can be.

In the present invention, a unit chip can be defined as an aggregate of semiconductor circuits formed in a unit area in which wafers are divided in a rectangular shape by scribe lanes in the horizontal and vertical directions. The wafer includes unit chips constituting a plurality of rows in the horizontal and vertical directions.

In the present invention, a semiconductor device has a multi-chip structure, and two unit chips connected to a single semiconductor substrate through a scribe lane correspond to a multi-chip. That is, the semiconductor device having a multi-chip structure according to the present invention includes two unit chips horizontally connected to a single semiconductor substrate through a scribe lane.

The term " wafer " means that a plurality of rows of unit chips are formed before the wafer is formed, and the semiconductor substrate is individualized into a semiconductor device due to wafer cutting.

The semiconductor module includes a semiconductor device and a substrate. The substrate may be a flexible printed circuit board capable of bonding a semiconductor device.

When the present invention is applied to a display device, it can be understood that one of the source driver and the timing controller is applied to the unit chip, and the semiconductor device includes two source drivers as two unit chips or one source driver and one The timing controller of FIG. The above case will be described in correspondence with each of the embodiments described later. At this time, the semiconductor module can be bonded to the glass of the display panel by the COG method or to the flexible circuit board by the COF method.

And, when the present invention is applied to a display device, the semiconductor module can be understood as a COF module in which a semiconductor device is bonded to a flexible circuit board.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

1 is a plan view showing a preferred embodiment of a semiconductor device of a multi-chip structure of the present invention.

The semiconductor device PKG of FIG. 1 includes a first semiconductor chip CH1, a scribe line SL, and a rectangular second unit chip CH2 formed on a single semiconductor substrate, . The semiconductor device PKG of Fig. 1 is configured to have a rectangular shape.

The first unit chip CH1 has a rectangular first surface in the bonding direction, and the first input pads IP1 and the first output pads OP1 are formed on the first surface.

The second unit chip CH2 has a second rectangular surface in the bonding direction, and the second input pads IP2 and the second output pads OP2 are formed on the second surface.

The scribe line SL is formed between the first unit chip CH1 and the second unit chip CH2.

In the above, the bonding direction refers to the direction facing the flexible circuit board. That is, the first surface of the first unit chip CH1 and the second surface of the second unit chip CH2 face the flexible circuit board.

The first surface can be understood as the entire surface of the bonding direction of the first unit chip CH1 bonded to the bonding region of the glass by the COG method or bonded to the bonding region of the flexible circuit substrate by the COF method. The second surface may also be understood as the entire surface of the bonding direction of the second unit chip CH2 bonded to the bonding area of the glass by the COG method or bonded to the bonding area of the flexible circuit board by the COF method.

In the first unit chip CH1 and the second unit chip CH2, the first input pads IP1 and the second input pads IP2 may be arranged in a row, and the first output pads OP1 and the second output pads OP2 may be composed of a plurality of columns. The number and the row of the first input pads IP1 and the second input pads IP2 and the number and the row of the first output pads OP1 and the second output pads OP2, As shown in FIG.

The semiconductor device PKG constituted by the semiconductor package can be configured to have the same scale as the sum of the lengths of the first unit chip CH1, the scribe line SL and the second unit chip CH2.

The second input pads IP2 and the second output pads OP2 of the second unit chip CH2 are connected to the first input pads IP1 and the first output pads OP1 of the first unit chip CH1, They can have the same arrangement structure. Illustratively, the arrangement order of the respective pads of the first input pads IP1 and the second input pads IP2 of FIG. 1 is " A, B, C ... " &Quot; are formed in the same order.

The semiconductor device (PKG) of Fig. 1 can be manufactured using the wafer of Fig.

Referring to FIG. 2, the wafer includes unit chips divided by scribe lines (SL) formed in the longitudinal direction and the transverse direction and arranged in a deteriorated row.

Each unit chip has a pair of short sides facing each other and a pair of short sides facing each other. The length of the long side of each unit chip can be assumed to be 16,500 um as an example.

The scribe line SL dividing the unit chips means a space reserved on the wafer for sowing and can be assumed to have a width of 80 um.

Sling lines (SA) are defined in some scribe lanes (SL). The sawing line SA is defined corresponding to each scribe line SL in the longitudinal direction and defined for each of the two scribing lines SL in the horizontal direction.

Two unit chips surrounded by a sawing line SA are a sawing unit forming a semiconductor device. More specifically, the first unit chip CH1, the scribe line SL, and the second unit chip CH2 are included in the area of each sawing unit.

When the sawing is performed, the scribe lines SL of the boundary regions where different semiconductor devices PKG are formed are removed. That is, the semiconductor device PKG has a structure including two unit chips including a first unit chip CH1 and a second unit chip CH2 and one scribe lane, and may be bonded in a sawing state, Structure.

That is, the length PKG_S of the semiconductor device PKG is determined by the length CH1_S of the long side of the first unit chip CH1, the length CH2_s of the long side of the second unit chip CH2 and the width of the scribe line SL . When the numerical values shown above are substituted, the length of the semiconductor chip PKG is 33,080um (= 2 * 16,500um + 80um).

The semiconductor device PKG of Figs. 1 and 2 may be bonded to the bonding region of the glass by the COG method or may be bonded to the flexible circuit board FL of the semiconductor module of Fig. The semiconductor device PKG may be bonded using the bonding tool BT of FIG.

The bonding tool BT has two bonding pads PD1 and PD2. Semiconductor devices PKG picked up on the bottom surfaces of the bonding pads PD1 and PD2 are shown.

When the four source drivers are bonded in line to the glass of the display panel by the COG method, the effect of the embodiment of the present invention can be understood as follows in comparison with the conventional case.

An embodiment of the present invention requires two individual semiconductor devices (PKG) each including a first unit chip (CH1) and a second unit chip (CH2).

The bonding tool BT distributes and picks up two semiconductor devices PKG to the respective bonding pads PD1 and PD2 to adhere to the glass and then bonding.

Each semiconductor device (PKG) individualized to include two unit chips according to the present invention has a length of 33,080um (= 2 * 16,500um + 80um) which is the sum of the widths of one scribe lane and the lengths of the long axes of two unit chips .

The length of the semiconductor device PKG is set such that the bondable chip sizes PS1 and PS2 of the bonding pads PD1 and PD2 of the bonding tool BT and the chips picked up on the required bonding pads PD1 and PD2 An exemplary minimum space (CS) of 5,000 um can be met.

The total bonding length according to the embodiment of the present invention is the sum of the lengths 66,180um (= 2 * 33,080um) of the two semiconductor devices PKG and the minimum spacing distance 5,000um between the bonding pads PD1 and PD2, 66,180um + 5,000um) is required.

However, in the conventional case, the source driver is individualized for each unit chip. Therefore, when four source drivers are bonded to the glass of the display panel in a line, the total bonding length is equal to the sum of the lengths of the four source drivers of 66,000um (= 4 * 16,500um) and the minimum A total length of 81,000 um (= 66,000 um + 15,000 um) including the sum of the spaces (CS) of 15,000 um (= 3 x 5,000 um) is required.

It can be seen that the embodiment of the present invention reduces the total bonding length compared with the conventional one. Therefore, according to the embodiment of the present invention, it is possible to bond unit chips, such as a source driver, with a high density.

An embodiment of the present invention can bond unit chips with high density by applying a semiconductor device (PKG) to the semiconductor module of Fig.

Referring to FIG. 3, a semiconductor device PKG is bonded to a predetermined bonding region of the flexible circuit board FL. The bonding area in the flexible circuit board FL can be understood as a surface covered by the semiconductor device PKG by bonding and can be set in the central area of the flexible circuit board FL in general.

The flexible circuit board FL has input terminals IT at the first end of the upper side, input lines IL connecting the bonding regions with the input terminals IT, a second end opposite to the first end, And output lines OL connecting the output terminals OT and the output terminals OT and the bonding areas are formed on one surface. Here, the input terminals IT correspond to the sum of the first unit chip CH1 of the semiconductor device PKG and the first and second input pads IP1 and IP2 of the second unit chip CH2 And the output terminals OT are connected to the first unit chip CH1 of the semiconductor device PKG and the sum of the first and second output pads OP1 and OP2 of the second unit chip CH2 As shown in FIG. The input lines IL and the output lines OL can be formed so as to have a pattern that is spread over a wide area while traveling from the bonding region to the input terminals IT or the output terminals OT.

Corresponding to the case where the four source drivers are bonded to the flexible circuit board FL of FIG. 3 in the COF manner, the effect of the embodiment of the present invention can be understood as follows in comparison with the conventional case.

In the embodiment of the present invention, two semiconductor devices (PKG) including a first unit chip CH1 and a second unit chip CH2 are bonded to a single flexible circuit board FL. Therefore, two flexible printed circuit boards (FL) are required for the bonding of the four source drivers.

However, in the case where the source driver is bonded to each flexible circuit board FL one by one as in the prior art, four flexible circuit boards FL are required for bonding the four source drivers. That is, it can be seen that the conventional method requires a longer length for the two flexible circuit boards FL.

Therefore, the embodiment of the present invention can obtain the effect of bonding unit chips, such as a source driver, with a high density even in COF bonding as shown in FIG.

The embodiment of the present invention can improve the ease of design and design for a semiconductor device (PKG), a semiconductor module, and an apparatus using the semiconductor module as the mounting density is improved.

On the other hand, the first unit chip CH1 and the second unit chip CH2 included in one semiconductor device PKG may have the same structure and the same function, or may have different structures and different functions .

Illustratively, the first unit chip CH1 and the second unit chip CH2 can be designed as a source driver. Further, the first unit chip CH1 may be designed as a source driver, and the second unit chip CH2 may be designed as a timing controller. The bonding density of the components can be increased for various applications according to the above-mentioned design change.

Also, the embodiment of the present invention is characterized in that the first input pads IP1 and the first output pads OP1 of the first unit chip CH1 included in one semiconductor device PKG and the second unit pads CH2 The second input pads IP2 and the second output pads OP2 of the second output pads OP2 may be variously modified to provide various options for increasing the bonding density of the components or reducing the wiring density.

First, as shown in FIG. 5, the semiconductor device PKG is configured such that the second input pads IP2 and the second output pads OP2 of the second unit chip CH2 are connected to the first input of the first unit chip CH1 The first output pads OP1 and the scribe lanes SL may be arranged symmetrically with respect to the pads IP1 and the first output pads OP1 and the scribe lane SL.

Illustratively, the arrangement order of the pads of the first input pads IP1 and the second input pads IP2 of Fig. 5 is " A, B, C ... " &Quot;, respectively.

When the semiconductor device PKG is configured as in the embodiment of FIG. 5, the flexible circuit board FL of the semiconductor module is connected to a first one of the first input pads IP1 closest to the scribe line SL The first input line SIL shared by the second input pad IP2: A closest to the scribe line SL among the input pad IP1: A and the second input pads IP2 may be configured.

6 is merely an example of sharing one input line (SIL), and a plurality of input lines (IL) are connected to the first unit chip (CH1) and the second unit chip CH2 < / RTI > by symmetrically sharing the input pads.

In FIGS. 5 and 6, the same components are denoted by the same reference numerals as those of FIG. 1 and FIG. 3, and redundant description is omitted.

 7, in the semiconductor device PKG, the second input pads IP2 and the second output pads OP2 of the second unit chip CH2 are connected to each other via the first unit chip CH1, May have the same arrangement structure as the first input pads IP1 and the first output pads OP1 when they are rotated 180 degrees.

Illustratively, the first input pads IP1 of the first unit chip CH1 are disposed adjacent to the long side of the upper portion and the second input pads IP2 of the second unit chip CH2 are disposed at the lower long side Respectively. That is, the first input pads IP1 of the first unit chip CH1 and the second input pads IP2 of the second unit chip CH2 are connected to the first unit chip CH1, the scribe line SL, And the second unit chip (CH2) is disposed at a position crossing in the succeeding longitudinal direction.

The first output pads OP1 of the first unit chip CH1 are disposed adjacent to the lower long side and the second output pads OP2 of the second unit chip CH2 are adjacent to the upper long side . That is, the first output pads OP1 of the first unit chip CH1 and the second output pads OP2 of the second unit chip CH2 are connected to the first unit chip CH1, the scribe line SL, And the second unit chip (CH2) is disposed at a position crossing in the succeeding longitudinal direction.

The semiconductor device PKG of FIG. 7 additionally includes first input pads IP1 and first output pads OP1 of the first unit chip CH1 and first and second output pads OP1 and OP2 of the first unit chip CH1 on the basis of the scribe line SL. The second input pads IP2 and the second output pads OP2 of the unit chip CH2 are symmetrical.

For example, the arrangement order of the pads of the first input pads IP1 and the second input pads IP2 in Fig. 7 is " A, B, C ... based on the scribe line SL. &Quot;, respectively.

7, the first output pads OP1 of the first unit chip CH1 are formed adjacent to the long side near the output terminals OT1, and the second output pads OP1 of the second unit chip CH2 Pads OP2 are formed adjacent to the output terminals OT2 at a long side.

Therefore, the first unit chip CH1 can form the first output line OL1 with the structure shown in FIG. 8 and the second unit chip CH2 can form the second output line OL2 with the structure shown in FIG. Can be formed.

8 and 9, the upper portion of the flexible circuit board FL is referred to as a first layer, and the lower portion thereof is referred to as a second layer. The output terminals OT of the first layer corresponding to the first unit chip CH1 are typically denoted as " first output terminal OT1 ", and the output terminals OT of the first layer corresponding to the first unit chip CH1, The output lines OL of the layer are typically referred to as " first output lines OL1 ". The output terminals OT of the first layer corresponding to the second unit chip CH2 are typically represented by a "second output terminal OT2", and the output terminals OT of the second layer corresponding to the second unit chip CH2 are represented by " The output lines OL of the layer are typically referred to as " second output lines OL2 ".

8, a first output terminal OT1 and a first output line OL1 corresponding to a first unit chip CH1 are formed in a first layer of a flexible circuit board FL, The unit chip CH1 and the second unit chip CH2 are bonded.

Both ends of the first output lines OL1 are connected to the first output pad OP1 and the first output terminal OT1 of the first unit chip CH1 by extending in the longitudinal direction in the first layer.

Referring to FIG. 9, a second output line OL2 corresponding to the second unit chip CH2 is formed in the second layer of the flexible circuit board FL.

Both ends of the second output line OL are connected to the second output pad OP2 of the first unit chip CH1 bonded to the first layer through the via holes BH1 and BH2 of the flexible circuit board FL, Layer to the second output terminal OT2.

In Fig. 9, the reference numerals IB and OB can be understood as an extension of the second output pad OP2 and the second input pad IP2 of the second unit chip CH2 for electrical connection.

7 to 9, the first unit chip CH1 and the second unit chip CH2 have first output pads OP1 and second outputs OP1 and OP2 at different positions corresponding to the output terminals OT, Even when the pad OP2 is arranged, the output lines OL can be smoothly formed while reducing the wiring density.

10, the semiconductor device PKG is connected to the first input pads IP1 and the first output pads OP1 of the first unit chip CH1 and the second input pads OP1 of the second unit chip CH2, The pads IP2 and the second output pads OP2 may be longitudinally crossed.

Illustratively, the arrangement order of the pads of the first input pads IP1 and the second input pads IP2 in Fig. , C, B, and A ".

In the semiconductor device PKG of Fig. 10, the first unit chip CH1 and the second unit chip CH2 also have a structure such as shown in Figs. 8 and 9 in which the wiring density is reduced according to the positions of the output terminals OT The output lines Ol can be formed smoothly.

Claims (12)

A first unit chip in which first input pads and first output pads are formed;
A second unit chip in which second input pads and second output pads are formed; And
And a scribe lane between the first unit chip and the second unit chip,
Wherein the first unit chip, the scribe lane, and the second unit chip are formed on the same semiconductor substrate and extend in the longitudinal direction of the long side of the first unit chip. The method according to claim 1,
Wherein the semiconductor package has a scale equal to a sum of lengths of the first unit chip, the scribe lane, and the second unit chip. The method according to claim 1,
Wherein the second input pads and the second output pads of the second unit chip have the same arrangement structure as the first input pads and the first output pads of the first unit chip, . The method according to claim 1,
Wherein the second input pads and the second output pads of the second unit chip are arranged symmetrically with respect to the first input pads and the first output pads of the first unit chip and the scribe lanes, The semiconductor device having a multi-chip structure. The method according to claim 1,
The second input pads and the second output pads of the second unit chip are the same as the first input pads and the first output pads when the first unit chip rotates 180 degrees with respect to the center A semiconductor device having a multi-chip structure having a layout structure. The method according to claim 1,
Wherein the first unit chip and the second unit chip have different functions and structures. A semiconductor device having a rectangular shape and in which the first unit chip, the scribe lane, and the second unit chip are formed in the same semiconductor substrate in the longitudinal direction of the long side; And
An input line connecting the input terminals of the first end and the bonding region, an output line connecting the output terminals of the second end opposite to the first end to the bonding region, And a flexible circuit board formed on the flexible circuit board,
The first input pads formed on the first unit chip and in contact with the bonding region and the second input pads formed on the second unit chip and contacting the bonding region are connected to ends of the input lines extended to the bonding region, Electrically connected,
First output pads formed on the first unit chip and in contact with the bonding region and second output pads formed on the second unit chip and contacting the bonding region are connected to end portions of the output lines extended to the bonding region, Wherein the semiconductor chip is electrically connected to the semiconductor chip. 8. The method of claim 7,
Wherein the second input pads and the second output pads of the second unit chip have the same arrangement structure as the first input pads and the first output pads, . 8. The method of claim 7,
Wherein the second input pads and the second output pads of the second unit chip are arranged symmetrically with respect to the first input pads and the first output pads of the first unit chip and the scribe lane Semiconductor module using a semiconductor device having a multi-chip structure having a structure. 10. The method of claim 9,
Wherein the input line includes a first input pad closest to the scribe lane among the first input pads and a first input line shared by the second input pad closest to the scribe lane among the second input pads A semiconductor module using a semiconductor device having a multi-chip structure. 8. The method of claim 7,
The second input pads and the second output pads of the second unit chip are arranged in the same arrangement as the first input pads and the first output pads when the first unit chip is rotated 180 degrees with respect to the center Semiconductor module using a semiconductor device having a multi-chip structure having a structure. 12. The method of claim 11,
A first output line corresponding to the first unit chip among the output lines is formed in a first layer of the flexible circuit board,
A second output line corresponding to the second unit chip among the output lines is formed in the second layer of the flexible circuit board,
Both ends of the first output lines being connected to the first output pad and the output terminals of the first unit chip of the one layer by extension,
Chip structure in which both ends of the second output lines are connected to the second output pad and the output terminals of the second unit chip of the first layer through via holes of the flexible circuit board, .

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