JP2003289122A - Ball-grid-array type semiconductor device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To realize a highly reliable BGA-type semiconductor device by suppressing the disconnection of conductive wiring and breakage of an external terminal. <P>SOLUTION: Respective insulating films 3 covering respective lands 2b are separated from each other, and a dummy wiring 10 in addition to conductive wiring 2 connected to the lands 2 is projected from a side face 3b of the insulating film 3 covering the lands 2b. Thus, it is possible to increase the rate of wiring materials whose rigidity is large inside the insulating film 3, and to strengthen the constraint of the thermal deformation of the insulating film 3 itself by the dummy wiring 10. Also, it is possible to suppress the peeling of the side face 3b of the insulating film by the conductive wiring 2 and the dummy wiring 10, and to reduce the increase of the thermal deformation quantity of the insulating film 3 due to the generation of the peeling of the side face 3b. <P>COPYRIGHT: (C)2004,JPO

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a semiconductor device composed of an insulating tape provided with conductive wiring for electrically connecting a semiconductor element and an external terminal, and in particular, the external terminal has a spherical solder. The present invention relates to a ball grid array type semiconductor device formed from the above.

[0002]

2. Description of the Related Art A ball grid array (BGA) type semiconductor device suitable for high pin count, small size and high speed has been put into practical use in order to cope with high density mounting of the semiconductor device. This BGA type semiconductor device is
It has a structure in which external terminals such as solder bumps are two-dimensionally arranged in an array.

In the BGA type semiconductor device, a member called an interposer in which conductive wiring is formed on the surface or on the surface and inside is used for electrical connection between the semiconductor element and the external terminal. For the interposer, a printed wiring board based on glass / epoxy, etc.,
Insulating tapes and the like having conductive wiring formed on the surface of polyimide or the like as a base material are used.

An example in which a semiconductor device is composed of an insulating tape on which conductive wiring is formed is disclosed in Japanese Patent Laid-Open No. 9-121002.
It is shown in the publication. FIG. 18 is a schematic sectional view of a BGA type semiconductor device using a conventional insulating tape. Figure 1
8, the BGA type semiconductor device includes a semiconductor element 1,
The conductive wiring 2 is formed on the surface, and the insulating tape 4 having the insulating film 3 formed so as to open a part of the bonding pad portion 2a and the like, and the semiconductor element 1 are fixed to the surface of the insulating tape 4. Sealing for sealing the adhesive member 5, the thin metal wire 6 for electrically connecting the semiconductor element 1 and the conductive wiring 2, the semiconductor element 1, the thin metal wire 6 and the semiconductor element fixing surface 4a of the insulating tape 4. It is composed of a resin 7 and an external terminal 8.

A bonding pad 2a to which the thin metal wire 6 is connected and a land 2b to which the external terminal 8 is connected are connected to the conductive wiring 2.

The insulating film 3 is called a solder resist, a photoresist or the like, and the screen printing method,
It is formed by a photo method or the like. Materials such as epoxy resin, polyimide resin, and polybutadiene resin are used for the insulating film 3. The soldering material (Pb
-Sn eutectic solder) is used.

The thin metal wire 6 and the conductive wiring 2 are connected by a bonding pad 2a arranged outside the surface of the semiconductor element 1. In the part of the bonding pad 2a,
An opening 3a is formed in the insulating film 3 so that the thin metal wire 6 and the bonding pad 2a can be bonded to each other.

The external terminal 8 is the mounting surface 4 of the insulating tape 4.
They are provided in the form of an array in b, and are arranged in the plane below the semiconductor element 1. In order to electrically connect the external terminal 8 arranged in the surface of the semiconductor element 1 and the semiconductor element 1,
The conductive wiring 2 is continuously formed from the bonding pad 2a to the land 2b located in the surface of the semiconductor element 1.

An opening 9 reaching the land 2b is provided on the mounting surface 4b side of the insulating tape 4 on which the land 2b is formed, and the land 2b and the external terminal 8 can be joined at this opening 9. It is like this.

[0010]

In the conventional BGA type semiconductor device shown in FIG. 18, silicon (Si) is used.
The linear expansion coefficient of the semiconductor element 1 made of 2 to 3 × 10 ⁻⁶
/ ° C, insulation tape 4 made of polyimide resin, etc.
Has a linear expansion coefficient of about 10 × 10 ⁻⁶ / ° C,
There is a large difference in the linear expansion coefficient between the two.

When a temperature change is applied to the conventional BGA type semiconductor device having such a structure, thermal stress due to the difference in linear expansion coefficient between the semiconductor element 1 and the insulating tape 4 is generated at the interface between the two. In some cases, cracks or peeling may occur in the adhesive member 5 that bonds the two.

Further, in the conventional BGA type semiconductor device shown in FIG. 18, the semiconductor tape fixing surface side 4a of the insulating tape 4 is formed.
The sealing resin 7 is formed only on the. Therefore, BGA
When a temperature change is applied to the mold semiconductor device, the semiconductor device is warped and deformed due to the expansion and contraction of the sealing resin 7, whereby tensile and compressive loads act on the insulating tape 4.

Since the insulating tape 4 is adhered to the semiconductor element 1 having high rigidity by the adhesive member 5, a large stress is generated at the interface between the two and the adhesive member 5 is cracked or peeled.

Thus, the conventional BGA shown in FIG.
In the type semiconductor device, there is a high possibility that cracks or peeling will occur in the adhesive member 5 due to at least one of the causes described above.

When the adhesive member 5 is cracked or peeled off, the insulating film 3 having a large coefficient of linear expansion is not constrained by the adhesive member 5 and can be freely thermally deformed. Therefore, the stress generated due to the difference in linear expansion coefficient between the semiconductor element 1 and the insulating film 3 is concentrated on the end portion of the insulating film 3.

When the insulating film 3 is formed so as to cover the entire lower surface of the semiconductor element 1 and the end portion of the insulating film 3 is substantially aligned with the end portion of the semiconductor element 1, the end portion of the semiconductor element 1 is large. Stress is generated.

Therefore, in order to prevent the stress from concentrating on the end portions of the semiconductor element 1, the insulating film 3 is provided so as to cover at least the individual lands 2b in the plane of the semiconductor element 1, and the insulating films 3 are mutually arranged. It is conceivable to configure so as to form independently.

By the way, as described above, the insulating film 3 which is no longer constrained by the adhesive member 5 is freely deformed by heat. In particular, in the cooling process, the contraction of the insulating film 3 itself causes a force to open the side surface side interface between the insulating film 3 and the adhesive member 5. Further, the insulating tape 4 is pulled outward by the deformation of the semiconductor device due to the contraction of the sealing resin 7.

Therefore, as described above, when the insulating films 3 are formed independently of each other, a force in the opening direction is further applied to the side surface side interface of the insulating film 3, and by repeating this process. Peeling occurs on the side surface of the insulating film 3.

Further, due to repeated changes in temperature, cracks may progress from the exfoliation tip on the side surface of the insulating film 3 to the inside of the conductive wiring 2 and cause disconnection. If the conductive wiring 2 is broken, the semiconductor device will not function properly, and the reliability of the BGA type semiconductor device will be significantly reduced.

The inventor of the present application has found that the conventional BG shown in FIG.
About A type semiconductor device, 150 ° C in 20 minutes → -5
An experiment was conducted by changing the temperature to 5 ° C. and using this as one cycle. As a result, in some cases, the conductive wiring 2 was broken in about 500 cycles.

Further, the conventional BGA type semiconductor device shown in FIG. 18 has a structure in which the external terminals 8 are arranged in the plane of the semiconductor element 1. Semiconductor devices are usually glass /
It is used by mounting it on a mounting board whose base material is epoxy resin. When a temperature change is applied to the mounted semiconductor device, stress due to the difference in linear expansion coefficient between the semiconductor device and the mounting substrate is generated in the external terminal 8.

This stress is greatest in the external terminal 8 located at the end of the semiconductor element 1 having the smallest linear expansion coefficient in the semiconductor device, and there is a high possibility that the external terminal 8 will break. If the external terminal 8 breaks, the semiconductor device will not function properly and the reliability of the semiconductor device will be significantly reduced.

An object of the present invention is to realize a highly reliable BGA type semiconductor device which suppresses disconnection of conductive wiring and breakage of external terminals.

[0025]

The above-mentioned object can be solved by adopting a means for reducing or restraining the thermal deformation amount of the insulating film caused by the crack or peeling of the adhesive member. Further, it can be solved by adopting a means for reducing the warp deformation amount of the semiconductor device.

To achieve the above object, the present invention is configured as follows. (1) In a ball grid array type semiconductor device, a plurality of pads and a plurality of lands, and a plurality of insulating films formed so as to cover each of the plurality of lands at least in the plane of the semiconductor element and separated from each other, An insulating tape having a plurality of conductive members extending from each of the plurality of lands and protruding from the insulating film; and an insulating tape fixed to the surface of the insulating tape by an adhesive member, and a metal thin wire through the pad to form the insulating tape. A rectangular semiconductor element electrically connected to a conductive member, a sealing resin for sealing the periphery of the semiconductor element and a semiconductor element fixing surface of the insulating tape, and an external terminal joined to the land. , Is provided.

The conductive member is formed of copper (Cu) or a material obtained by plating the surface of copper, and the material used for these conductive members usually has a larger elastic coefficient than the material used for the insulating film. .

Therefore, the deformation of the insulating film when the temperature changes is
It is designed to be bound to a large extent by the conductive wiring covered by the insulating film.

By projecting a plurality of conductive members from the insulating film formed so as to cover each land so as to cross the side surface of the insulating film, peeling of the side surface of the insulating film can be suppressed. By suppressing the peeling of the side surface of the insulating film, the peeled area is reduced and the thermal deformation amount of the insulating film is reduced. In addition, since the ratio of the conductive member occupying inside the insulating film also increases, the amount of thermal deformation of the insulating film is reduced by restraining the conductive member.

It is not necessary that all the conductive members extending from each land are electrically connected to the semiconductor element. The protruding end of the conductive member may be interrupted as long as it can project from the insulating film and restrain the thermal deformation of the insulating film. Such a conductive member that is not electrically connected is formed as a dummy wiring on the surface of the insulating tape.

(2) Preferably, in the above (1),
Of the plurality of conductive members extending from each of the plurality of lands and protruding from the insulating film, at least one conductive member is electrically connected to the semiconductor element, and another conductive member is at least It is formed at a position sandwiching the electrically connected conductive member.

(3) Further, in the above (2), preferably, with respect to a straight line connecting the center point of one land to the electrically conductive member to be electrically connected, the center point is the center of rotation, At least one other conductive member is formed in a region rotated by 90 ° to one side of the straight line, and at least one other conductive member is formed in a region rotated by 90 ° to the other side of the straight line. Forming a conductive member.

If at least one conductive member is electrically connected to the semiconductor element and another conductive member is formed at a position sandwiching at least the electrically connected conductive member, the insulating film The thermal deformation can be restrained in a well-balanced manner, and the stress generated in the conductive member can be leveled and reduced.

(4) Further, in the above (1) or (2), preferably, the width of the conductive member protruding from the insulating film inside the insulating film is wider than the width outside the insulating film.

If the width of the conductive member protruding from the insulating film is formed wider inside the insulating film than outside, the ratio of the conductive member in the insulating film increases.
The amount of deformation of the insulating film can be reduced.

In addition to the effect of reducing the amount of deformation of the insulating film, the widening of the conductive member has the effect of prolonging the life (the number of repeated temperature changes) until the wire breaks even if a crack occurs in the conductive member. To be

(5) In the ball grid array type semiconductor device, an insulating tape having conductive wirings, lands formed with pads and projections connected to the conductive wirings, and the conductive wirings and an insulating film. And a rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and the semiconductor element fixing surface of the periphery of the semiconductor element and the insulating tape. And an external terminal joined to the land.

(6) Further, an insulating tape having a plurality of pads and a plurality of lands, an insulating film covering the plurality of lands at least in the plane of the semiconductor element, and a conductive wiring connected to the pads and the lands. And a rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and a semiconductor element fixing surface of the periphery of the semiconductor element and the insulating tape. In a ball grid array type semiconductor device having an encapsulating resin for encapsulating and an external terminal joined to the land, the insulating film is a plurality of insulating films separated from each other. Are formed so as to cover the individual lands, and projections protruding from the insulating film are formed on the lands.

By forming protrusions on the land covered with the insulating film, in addition to the conductive wiring extending from the land, the protrusions made of the same material as the conductive wiring can restrain the insulating film, and the heat of the insulating film can be restrained. The amount of deformation can be reduced.

When the insulating film covers individual lands, protrusions are formed on each land so as to project from the insulating film. By forming such protrusions, peeling of the side surface of the insulating film is divided, so that the amount of thermal deformation of the insulating film can be reduced.

(7) Preferably, in the above (6),
A plurality of protrusions are formed on the land and are formed at least at positions sandwiching the conductive wiring.

(8) Further, in the above (7), preferably, one side of the straight line with the center point as a rotation center with respect to a straight line connecting the center point of one land to the conductive wiring. Forming at least one of the projections in a region rotated by 90 ° on the other side, and forming 90 ° on the other side of the straight line
At least one of the protrusions is formed in the rotated region.

The protrusions formed on the lands are positioned so as to sandwich the conductive wiring extending from the land, and are formed at least at two positions on both sides of the conductive wiring, so that the insulating film around at least the conductive wiring is thermally deformed. The amount can be reduced,
It is possible to prevent a large stress from occurring in the conductive wiring located at the lower end of the side surface of the insulating film.

(9) Further, preferably, the above (5),
In (6), (7) or (8), the width of the conductive wiring connected to the land inside the insulating film is wider than the width outside the insulating film.

When the width of the conductive wiring protruding from the insulating film is formed wider inside the insulating film than outside, the ratio of the conductive wiring in the insulating film is increased.
The amount of deformation of the insulating film can be reduced.

(10) In the ball grid array type semiconductor device, a plurality of conductive wirings, a plurality of pads and lands connected to the conductive wirings, an insulating film are provided, and a slit is formed on the board mounting surface side. And a rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and the surroundings of the semiconductor element and the insulating property. A sealing resin for sealing the semiconductor element fixing surface of the tape and an external terminal joined to the land are provided.

As described above, in the ball grid array type semiconductor device, the insulating tape receives a tensile load due to the deformation of the semiconductor device due to the shrinkage of the sealing resin. When the slit is provided on the board mounting surface side of the insulating tape, the tensile load due to the deformation of the semiconductor device is taken up by the insulating tape outside from the slit position.

Therefore, by providing the slits at appropriate positions, it is possible to reduce the tensile load applied to the outside of the insulating tape at the location where the conductive wiring is broken. This makes it possible to reduce the stress generated at the lower end of the side surface of the insulating film.

(11) In the ball grid array type semiconductor device, conductive wiring, pads and lands connected to the conductive wiring, and an insulating film formed so as to cover at least the outer peripheral portion of the land are provided. An insulating tape having, a rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, a periphery of the semiconductor element and the insulating tape. A sealing resin for sealing the semiconductor element fixing surface and an external terminal joined to the land are provided.

In the land arranged in the plane of the semiconductor element, the insulating film is formed so as to cover the outer peripheral portion of the land, and the adhesive member is formed so as to cover the land in the central portion of the land. As a result, the volume of the insulating film can be reduced, and the amount of thermal deformation of the insulating film itself can be reduced.

Since the amount of thermal deformation of the adhesive member is usually smaller than the amount of thermal deformation of the insulating film, the thermal deformation of the insulating film can be restrained by the adhesive member covering the central portion of the land.

(12) Further, the conductive wiring, the pads and lands connected to the conductive wiring, the insulating tape having the insulating film, and the conductive tape fixed on the surface of the insulating tape by an adhesive member. Rectangular semiconductor element electrically connected to the conductive wiring by a fine metal wire, a sealing resin for sealing the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and an external member joined to the land Terminals,
In a ball grid array type semiconductor device having
The linear expansion coefficient of the sealing resin is equal to the linear expansion coefficient of the insulating tape.

When the linear expansion coefficient of the sealing resin for sealing the semiconductor element fixing surface of the insulating tape is made equal to the linear expansion coefficient of the insulating tape, the semiconductor device has a thermophysically balanced structure. .

As a result, the amount of warp deformation of the semiconductor device due to the shrinkage of the sealing resin can be reduced, and the tensile load generated on the insulating tape can be alleviated.

(13) Further, the conductive wire, the pad and the land connected to the conductive wire, the insulating tape having the insulating film, and the conductive tape are fixed to the surface of the insulating tape by an adhesive member. Rectangular semiconductor element electrically connected to the conductive wiring by a fine metal wire, a sealing resin for sealing the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and an external member joined to the land Terminals,
In a ball grid array type semiconductor device having
The linear expansion coefficient of the insulating film is equal to the linear expansion coefficient of the adhesive member.

If the coefficient of linear expansion of the insulating film and the coefficient of linear expansion of the adhesive member are made equal, the thermal deformation amounts of the insulating film and the adhesive member become substantially the same when the semiconductor device is subjected to temperature change, and therefore the insulating film. Peeling does not occur at the interface between the adhesive member and the adhesive member. In particular, since peeling does not occur on the side surface of the insulating film, it is possible to reduce stress concentration in a portion directly below the side surface of the insulating film.

(14) Further, in the ball grid array type semiconductor device, conductive wiring, pads and lands connected to the conductive wiring, an insulating tape having an insulating film, and a surface of the insulating tape. A rectangular semiconductor element fixed by an adhesive member and electrically connected to the conductive wiring, a deformation restraint member formed on the surface of the insulating tape, and the insulation around the semiconductor element and the deformation restraint member. A sealing resin for sealing the semiconductor element fixing surface of the conductive tape, and an external terminal joined to the land.

A deformation restraint member is formed on the surface of the insulating tape to reduce the warp deformation amount of the semiconductor device. Thereby, the tensile load generated on the insulating tape can be relaxed. Further, it is possible to reduce the strain generated in the solder bumps or the like which are the external terminals.

(15) Further, a plurality of conductive wirings, a plurality of pads and lands connected to the conductive wirings, an insulating tape having an insulating film, and an adhesive member fixed to the surface of the insulating tape. A rectangular semiconductor element electrically connected to the conductive wiring by a thin metal wire, a sealing resin for sealing the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and the land. In a ball grid array type semiconductor device having a plurality of external terminals to be joined, the distance from the semiconductor element side surface to the sealing resin side surface is not less than the interval between the external terminals, at least from the semiconductor element side surface. The external terminals are arranged between the side surfaces of the sealing resin. When the semiconductor device is mounted on a substrate by arranging the external terminals outside the lower surface of the semiconductor element, that is, between the side surface of the semiconductor element and the side surface of the sealing resin, it is positioned outside the lower surface of the semiconductor element. The external terminals that perform the operation restrain the deformation of the semiconductor device.

This makes it possible to reduce the strain generated in the external terminals located in the lower surface of the semiconductor element,
It is possible to prevent breakage of the external terminal.

(16) Further, an insulating tape having a plurality of pads and a plurality of lands, an insulating film covering the plurality of lands at least in the plane of the semiconductor element, and a conductive wiring connected to the pads and the lands. And a rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and a semiconductor element fixing surface of the periphery of the semiconductor element and the insulating tape. In a ball grid array type semiconductor device having an encapsulating resin for encapsulating and an external terminal joined to the land, the insulating film is a plurality of insulating films separated from each other. Is formed so as to cover each of the lands, and the conductive wiring connected to the lands has a width inside the insulating film wider than that outside the insulating film. . If the width of the conductive wiring is formed wider inside the insulating film than outside, the proportion of the conductive wiring in the insulating film is increased, and the amount of deformation of the insulating film can be reduced.

In addition to the effect of reducing the amount of deformation of the insulating film, widening the conductive wiring has the effect of prolonging the life of the conductive wiring even if a crack occurs in the conductive wiring.

[0063]

DETAILED DESCRIPTION OF THE INVENTION Embodiments of the present invention will be described below with reference to the accompanying drawings. FIG. 1 is a diagram showing a first embodiment of a ball grid array type semiconductor device according to the present invention, and is a plan view with a semiconductor element, a sealing resin and an insulating film removed. 2 is a sectional view of the semiconductor device shown in FIG.

As shown in FIGS. 1 and 2, the first aspect of the present invention is as follows.
In the semiconductor device according to the first embodiment, the insulating tape 4 on which the conductive wiring 2 is formed, the semiconductor element 1 fixed to the insulating tape 4 by the adhesive member 5, the semiconductor element 1 and the conductive wiring 2 are electrically connected. The thin metal wires 6 that are electrically connected to each other, the sealing resin 7 that covers the semiconductor element 1, the thin metal wires 6 and the surface of the insulating tape 4 and the external terminals 8 are provided.

On the fixing surface 4a of the insulating tape 4 on the semiconductor element 1 side, the bonding pad 2a to which the thin metal wire 6 is bonded, the plurality of lands 2b to which the plurality of external terminals 8 are respectively bonded, and the conductivity. Wiring 2 is provided. The respective upper surfaces and side surfaces of the lands 2b located in the lower surface of the semiconductor element 1 on the center side of the bonding pad 2a are covered with an insulating film 3 provided for each land 2b. Further, the conductive wiring 2 is extended on the surface of the insulating tape 4 to electrically connect the land 2b and the bonding pad 2a.

Land 2b located in the plane of semiconductor element 1
In addition to the conductive wiring 2 electrically connected to the bonding pad 2a, the dummy wiring 10 which is not connected to the bonding pad 2a is extended. The dummy wiring 10 projects from the side surface 3b of the insulating film 3 that covers the land 2b, and the tip thereof extends to the outside of the insulating film 3. That is, the length of the dummy wiring 10 is equal to the land 2
The length is such that the side surface b is exposed to the outside of the side surface of the insulating film 3. The dummy wiring 10 is provided on the surface of the insulating tape 4 similarly to the conductive wiring 2, and is formed by the same process as the conductive wiring 2.

For the conductive wiring 2, a copper (Cu) foil or a copper foil having a surface plated with gold (Au), nickel (Ni) or the like is used. The bonding pad 2a and the land 2b connected to the conductive wiring 2 are also made of the same material, but plating or the like may be applied according to each location in order to improve the bonding property.

The land 2 is provided on the mounting surface 4b of the insulating tape 4.
The opening 9 is formed to penetrate to the land 2b.
An external terminal 8 is joined to the via via an opening 9. Therefore, the external terminals 8 are formed below the semiconductor element 1 and are arranged in an array as shown in FIG.

A solder material (for example, Pb) is used for the external terminal 8.
-Sn-based eutectic solder) or the like, and after arranging a spherical solder material or paste-like solder material in the opening 9,
The solder is melted and joined to the land 2b.

The semiconductor element 1 is fixed to the semiconductor element fixing surface 4a of the insulating tape 4 by the adhesive member 5.
Further, an electrode (not shown) is formed on the upper surface of the semiconductor element 1, and by connecting the electrode and the bonding pad 2a on the surface of the insulating tape 4 with a thin metal wire 6, the semiconductor element 1 and the conductive element 4 are electrically conductive. The wiring 2 is electrically connected.

A material having an epoxy resin as a base material is used for the adhesive member 5. In addition, the thin metal wire 6 includes
A material such as gold (Au), silver (Ag) or aluminum (Al) is used.

The sealing resin 7 is composed of the semiconductor element 1 and the thin metal wire 6.
And the semiconductor element fixing surface 4a of the insulating tape 4 are formed. A material obtained by filling silica particles in an epoxy resin, which is a thermosetting resin, is used for the sealing resin 7, and is formed by a transfer molding method or a potting method.

As described above, according to the semiconductor device in the first embodiment of the present invention, the individual insulating films 3 that cover the individual lands 2b are separated from each other and also cover the lands 2b. By projecting the dummy wiring 10 in addition to the conductive wiring 2 connected to the land 2b from the side surface 3b of the wiring 3, it is possible to increase the proportion of the wiring material having high rigidity inside the insulating film 3 and to increase the insulating film. The constraint of thermal deformation of 3 itself can be strengthened by the dummy wiring 10.

Further, the peeling of the insulating film side surface 3b can be suppressed by the conductive wiring 2 and the dummy wiring 10, and an increase in the amount of thermal deformation of the insulating film 3 due to the peeling of the side surface 3b can be suppressed.

With this, it is possible to prevent the disconnection defect of the conductive wiring 2 which occurs at the lower end portion of the side surface of the insulating film 3 when the temperature of the semiconductor device is changed, and the disconnection of the conductive wiring is suppressed. It is possible to realize a highly reliable BGA type semiconductor device.

According to an experiment conducted by the inventor of the present application, the BGA type semiconductor device according to the first embodiment shown in FIG.
When the temperature was changed from 150 ° C. to −55 ° C. in 0 minutes and this was set as one cycle, the conductive wiring 2 was not broken even after about 2000 cycles.

The first embodiment shown in FIGS. 1 and 2 shows an example in which the dummy wiring 10 connected to the land 2b is provided on the land 2b arranged in the plane of the semiconductor element 1. This is because the land 2b located in the plane of the semiconductor element 1 in the semiconductor device configured as in the first embodiment.
This is because there is a high possibility that a disconnection defect will occur in the conductive wiring 2 connected to.

However, the formation of the dummy wiring is not limited to the land 2b arranged on the surface of the semiconductor element 1, and the dummy wiring 10 may be formed on the land 2b arranged outside the surface. Absent. Further, the dummy wiring 10 may be connected to the bonding pad 2a in the same manner as the conductive wiring 2, or the other lands 2b or the dummy wirings 10 or the conductive wiring 2 may be connected.

Further, in the first embodiment shown in FIGS. 1 and 2, an example of a semiconductor device in which the external terminals 8 joined to the lands 2b are arranged both outside and inside the semiconductor element 1 is shown. Although shown, it is of course applicable to an example in which the external terminals 8 are arranged only in the plane of the semiconductor element 1.

That is, the first embodiment of the present invention is shown in FIG.
The same can be applied to a semiconductor device in which all the external terminals 8 are arranged in the plane of the semiconductor element 1 as shown in FIG. In the example shown in FIG. 3, dummy wirings 10 are formed on all lands 2b.

FIG. 4 is a plan view showing another aspect of the first embodiment shown in FIGS. In the example shown in FIGS. 1 and 2, four dummy wirings 10 connected to the lands 2b are provided for each of the lands 2b arranged in the plane of the semiconductor element 1. Insulation film 3
The effect of restraining the thermal deformation is improved as the number of dummy wirings 10 increases.

However, if the spaces between the lands 2b are small, many dummy wirings 10 cannot be formed on the lands 2b. The number of the dummy wirings 10 may be one or plural as long as it can restrain the thermal deformation of the insulating film 3 itself and prevent the conductive wirings 2 from breaking.

However, in order to restrain the thermal deformation of the insulating film 3 in a well-balanced manner and to level the stress generated in the conductive wiring 2 to reduce it, as shown in FIG. It is desirable to form at least two dummy wirings 10 so as to sandwich the conductive wiring 2.

That is, with respect to a straight line connecting the center point of the land 2b to the extension line of the conductive wiring 2, the center point of the center of rotation is used as the center of rotation, and on one side of the straight line on the surface of the insulating tape 4. One dummy wiring 10 is formed in the region rotated by 90 °, and another dummy wiring 10 is formed in the region rotated by 90 ° on the other side of the straight line. Preferably, the dummy wiring 10 is formed in the region rotated by 45 ° on one side or the other side of the straight line.

FIGS. 5 and 6 are views for explaining another aspect of the first embodiment of the present invention shown in FIGS. 1 and 2.
FIG. 6 is a plan view showing the shapes of the conductive wiring 2 and the dummy wiring 10 connected to the land 2b.

In FIG. 5, the conductive wiring 2 and the dummy wiring 10 are connected to the land 2b, and these are projected from the insulating film 3 and extended. Conductive wiring 2
The width a inside the insulating film 3 is wider than the width b outside the insulating film 3, and the width outside becomes gradually constant and becomes a constant value. By setting the width of the conductive wiring 2 to such a configuration, it is possible to increase the function of reducing the thermal deformation amount of the insulating film 3 itself at least in the vicinity of the conductive wiring 2 by restraining the conductive wiring 2.

Further, by widening the wiring width in the vicinity of the portion protruding from the insulating film 3, even if a crack is generated in the wiring, it is possible to increase the life until the wire is completely broken. It is possible to prevent the occurrence of defects within the usage period of.

FIG. 6 shows an example in which, in addition to the conductive wiring 2 extending from the land 2b, a wide portion is formed in the dummy wiring 10 so that the width a inside the insulating film 3 is wider than the width b outside. With such a configuration, the thermal deformation amount of the insulating film 3 can be further reduced.

It is considered that the larger the inner width a and the outer width b of the conductive wiring 2 and the dummy wiring 10 in the insulating film 3, the greater the effect of reducing the amount of thermal deformation of the insulating film 3. The larger the value, the greater the possibility that noise will be mixed. Further, the size of the widths a and b is limited due to the relationship with the wiring such as the adjacent land 2b. Therefore, the widths a and b are determined based on the above-described noise mixture and the relationship with other wiring and the like.

FIG. 7 is a view showing a second embodiment of the ball grid array type semiconductor device according to the present invention, and is a plan view with the semiconductor element, the sealing resin and the insulating film removed. . 8 is a sectional view of the semiconductor device shown in FIG.

As shown in FIGS. 7 and 8, according to the second aspect of the present invention.
Similar to the first embodiment, the semiconductor device according to the first embodiment includes the insulating tape 4 on which the conductive wiring 2 is formed, the semiconductor element 1 fixed to the insulating tape 4 by the adhesive member 5, and the semiconductor device. A metal thin wire 6 that electrically connects the element 1 and the conductive wiring 2, a sealing resin 7 that covers the semiconductor element 1, the metal thin wire 6, and the surface of the insulating tape 4, and an external terminal 8 are provided.

A first embodiment shown in FIGS. 1 and 2, and
The difference from the second embodiment is that a plurality of protrusions 11 protruding from the insulating film 3 covering the land 2b are formed at least for the land 2b arranged in the lower surface of the semiconductor element 1. . Other configurations are the same as those of the first and second embodiments.
The protrusion 11 is made of copper (Cu) foil or the like like the land 2 b and the conductive wiring 2.

As described above, a plurality of protrusions 1 are formed on the land 2b.
By forming No. 1, the ratio of the wiring material having high rigidity in the insulating film 3 can be increased, and the thermal deformation of the insulating film 3 itself can be further restrained. Further, peeling of the side surface 3b of the insulating film 3 can be suppressed by the conductive wiring 2 and the protrusion 11, and an increase in the amount of thermal deformation of the insulating film 3 due to occurrence of peeling of the side surface 3b can be suppressed.

Thus, when the temperature of the semiconductor device is changed, it is possible to prevent the disconnection defect of the conductive wiring 2 which occurs at the lower end portion of the side surface of the insulating film 3 and suppress the disconnection of the conductive wiring. It is possible to realize a highly reliable BGA type semiconductor device.

The number of the protrusions 11 may be one or plural as long as it can restrain the thermal deformation of the insulating film 3 itself and prevent the disconnection of the conductive wiring 2. However, in order to restrain the thermal deformation of the insulating film 3 in a well-balanced manner and level and reduce the stress generated in the conductive wiring 2, as shown in FIG. It is desirable to form at least two protrusions 11 so as to sandwich the wiring 2.

That is, with respect to a straight line connecting the center point of the land 2b to the extension line of the conductive wiring 2, the center point of the center of rotation is used as the center of rotation, and on the surface of the insulating tape 4, one side of the straight line One protrusion 11 is formed in the region rotated by 90 °, and another protrusion 11 is formed in the region rotated by 90 ° on the other side of the straight line. Preferably, the protrusion 11 is formed in the region rotated by 45 ° on one side or the other side of the straight line.

Further, it is desirable that the conductive wiring 2 be formed with a wide portion such that the width a inside the insulating film 3 is wider than the width b outside as shown in FIG. In the conductive wiring 2, the width a inside the insulating film 3 is wider than the width b outside the insulating film 3, and the width outside becomes gradually narrow and becomes a constant value.

With such a configuration, the amount of thermal deformation of the insulating film 3 itself at least in the vicinity of the conductive wiring 2 can be reduced by restraining the conductive wiring 2 having the wide portion. Further, even if the wiring is cracked, it is possible to extend the life until the wire is completely broken, and it is possible to prevent the occurrence of defects within the normal use period.

FIG. 11 is a diagram showing a third embodiment of the ball grid array type semiconductor device according to the present invention, and is a plan view with the semiconductor element and the sealing resin removed. 12 is a sectional view of the semiconductor device shown in FIG.

As shown in FIGS. 11 and 12, in the semiconductor device according to the third embodiment of the present invention, the insulating tape 4 on which the conductive wiring 2 is formed and the adhesive member 5 are attached to the insulating tape 4. A fixed semiconductor element 1, a thin metal wire 6 that electrically connects the semiconductor element 1 and the conductive wiring 2, and a sealing resin 7 that covers the semiconductor element 1, the thin metal wire 6 and the surface of the insulating tape 4. The external terminal 8 is provided.

On the fixing surface 4a of the insulating tape 4 on the semiconductor element 1 side, a bonding pad 2a and a plurality of lands 2b are formed.
And a conductive wiring 2 are provided, and an insulating film 3 is provided so as to cover the land 2b located in the lower surface of the semiconductor element 1 on the center side of the bonding pad 2a. The insulating film 3 is provided for each land 2b. An opening 12 is formed in the central portion of the upper surface of the land 2b of the insulating film 3 that covers these lands 2b, and the adhesive member 5 penetrates into the inside of the opening 12.
It is in contact with the upper surface of the land 2b.

Therefore, the insulating film 3 is formed so as to cover the outer peripheral portion of the land 2b. The conductive wiring 2 is extended on the surface of the insulating tape 4 to electrically connect the land 2b and the bonding pad 2a. The mounting surface 4b of the insulating tape 4 has an opening 9 penetrating to the land 2b, and the external terminal 8 is joined to the land 2b through the opening 9.

The semiconductor element 1 is fixed to the semiconductor element fixing surface 4a of the insulating tape 4 by the adhesive member 5.
An electrode (not shown) is formed on the upper surface of the semiconductor element 1. By connecting the electrode and the bonding pad 2a on the surface of the insulating tape 4 with a thin metal wire 6,
The semiconductor element 1 and the conductive wiring 2 are electrically connected.

Further, the sealing resin 7 is formed so as to cover the semiconductor element 1, the thin metal wires 6 and the semiconductor element fixing surface 4a of the insulating tape 4.

As in the third embodiment, the insulating film 3
Has an opening 12 at a portion corresponding to the central portion of the upper surface of the land 2b, and has a structure in which the adhesive member 5 penetrates into the opening 12, so that the heat of the insulating film 3 itself due to the volume reduction of the insulating film 3 It is possible to reduce the amount of deformation, and it is possible to prevent disconnection failure of the conductive wiring 2 when the semiconductor device is subjected to temperature change, suppress the disconnection of the conductive wiring, and have a highly reliable BGA type. The effect that the semiconductor device can be realized is obtained.

The insulating film 3 is made of a material such as epoxy resin, polyimide resin or polybutadiene resin. On the other hand, the adhesive member 5 is made of an epoxy resin or a polyimide resin material filled with inorganic glass or the like. Usually, the linear expansion coefficient of the material for the adhesive member 5 is smaller than that of the material for the insulating film 3, so that the thermal deformation amount of the adhesive member 5 is smaller than the thermal deformation amount of the insulating film 3. Therefore, the opening 1 at the center of the upper surface of the land 2b
The deformation of the insulating film 3 can be restrained by the adhesive member 5 penetrating into 2.

FIG. 13 is a sectional view showing a fourth embodiment of a ball grid array type semiconductor device according to the present invention, and FIG. 14 is a semiconductor element of the semiconductor device shown in FIG. 13, an insulating film, and a sealing member. It is a top view in the state where resin was removed.

The basic structure of the semiconductor device according to the fourth embodiment is the same as that of the first embodiment described above, but the difference from the first embodiment is that no dummy wiring is formed. The slit 13 is formed in the insulating sheet 4 from the mounting surface 4b side of the insulating sheet 4.

The slit 13 is the mounting surface 4 of the insulating tape 4.
As shown in FIG. 14, it is desirable that the semiconductor device 1 is formed in a square shape along the outer shape 4 sides of the semiconductor element 1 so as not to penetrate the mounting surface 4b to the fixing surface 4a of the semiconductor element 1. Further, it is desirable that the slit 13 is formed immediately outside the land 2b where the disconnection failure occurs.

The slit 13 is formed in the insulating tape 4
When the semiconductor device is cooled, the contraction of the sealing resin 7 allows the tensile load acting on the insulating tape 4 to be relieved by the deformation of the slits 13.

As a result, on the lower surface side of the semiconductor element 1, the insulating tape 4 located closer to the center than the slit 13 is formed.
Therefore, a large tensile load is not applied, and the stress generated at the lower end portion of the side surface of the insulating film 3 arranged in this portion can be reduced.

In other words, it is possible to prevent disconnection failure of the conductive wiring 2 when the semiconductor device is subjected to temperature change, suppress the disconnection of the conductive wiring, and have a high reliability.
An effect that an A-type semiconductor device can be realized is obtained.

FIG. 15 is a sectional view showing a fifth embodiment of the ball grid array type semiconductor device according to the present invention, and FIG. 16 is a semiconductor element, an insulating film and a sealing member of the semiconductor device shown in FIG. It is a top view in the state where resin and a deformation restraint member were removed.

The basic structure of the semiconductor device according to the fifth embodiment is the same as that of the first embodiment described above, but the difference from the first embodiment is that no dummy wiring is formed. Then, the frame-shaped deformation restraining member 14 is formed on the outer peripheral portion of the semiconductor element 1 on the semiconductor element fixing surface 4 a of the insulating sheet 4.

The deformation restraint member 14 is made of a metal material such as copper (Cu), and is bonded to the semiconductor element fixing surface 4a of the insulating tape 4 outside the bonding pad 2a with an adhesive (not shown). The deformation restraining member 14 is sealed with the sealing resin 7 together with the semiconductor element 1 and the thin metal wires 6 after being bonded to the insulating tape 4.

The deformation restraining member 14 is constructed so as to have a rigidity higher than that of the insulating tape 4, and has a thickness of 0.1 mm.
A metal plate of about 0.2 mm processed into a predetermined shape is used.

By providing such a deformation restraint member 14 on the outer peripheral portion of the semiconductor element 1, it is possible to reduce the amount of warp deformation when the semiconductor device is subjected to temperature change.
A tensile load generated on the insulating tape 4 during cooling can be relaxed.

As a result, the stress generated at the lower end of the side surface of the insulating film 3 can be reduced. Further, of the strains generated in the external terminals 8 formed of solder or the like, the strain component caused by the warp deformation of the semiconductor device can be reduced. Therefore, breakage of the conductive wiring and breakage of the external terminal can be suppressed, and a highly reliable BGA type semiconductor device can be realized.

In the ball grid array type semiconductor device according to the present invention, it is desirable that the sealing resin 7 and the insulating tape 4 are made of materials having the same linear expansion coefficient.

Semiconductor device fixing surface side 4a of the insulating tape 4
The linear expansion coefficient of the sealing resin 7 for sealing the insulating tape 4
When the coefficient of linear expansion is made equal to, the semiconductor device has a thermophysical balanced structure. As a result, the amount of warp deformation of the semiconductor device due to the shrinkage of the sealing resin 7 can be reduced, and the effect of reducing the tensile load generated on the insulating tape 4 can be obtained.

Further, of the strains generated in the external terminals 8 formed of solder bumps or the like, the strain component resulting from the warp deformation of the semiconductor device can be reduced.

The sealing resin 7 is filled with silica particles. By adjusting the filling rate of the silica particles, the linear expansion coefficient of the sealing resin 7 is made equal to that of the insulating tape 4. Can be equivalent.

Further, in the ball grid array type semiconductor device according to the present invention, it is desirable that the insulating film 3 and the adhesive member 5 are made of materials having the same linear expansion coefficient.

If the insulating film 3 and the adhesive member 5 have the same linear expansion coefficient, the insulating film 3 and the adhesive member 5 have substantially the same amount of thermal deformation when the semiconductor device is subjected to temperature change. Peeling does not occur at the interface between the adhesive member 5 and. In particular, since peeling does not occur on the side surface 3b of the insulating film, it is possible to obtain an effect of reducing stress concentration on the lower side surface of the insulating film 3.

By filling the adhesive member 5 with inorganic glass particles or the like and adjusting the filling rate of the glass particles, the insulating film 3 and the adhesive member 5 can have the same linear expansion coefficient.

FIG. 17 is a sectional view for explaining the sixth embodiment of the ball grid array type semiconductor device according to the present invention. In the semiconductor device of the sixth embodiment shown in FIG. 17, the insulating tape 4 on which the conductive wiring 2 is formed, the semiconductor element 1 fixed to the insulating tape 4 by the adhesive member 5, the semiconductor element 1 and the conductive tape The thin metal wire 6 for electrically connecting the flexible wiring 2, the semiconductor element 1, the thin metal wire 6 and the sealing resin 7 for covering the surface of the insulating tape 4, and the external terminal 8 are provided.

Bonding pads 2a, lands 2b, and conductive wirings 2 are provided on the semiconductor element fixing surface 4a of the insulating tape 4, and the area other than the bonding pads 2a is covered with the insulating film 3. There is.

The land 2 is provided on the mounting surface 4b of the insulating tape 4.
The opening 9 is formed to penetrate to the land 2b.
An external terminal 8 is joined to the via via an opening 9.

The semiconductor element 1 is fixed to the semiconductor element fixing surface 4a of the insulating tape 4 by the adhesive member 5.
Further, an electrode (not shown) is formed on the upper surface of the semiconductor element 1, and the electrode and the bonding pad 2a on the surface of the insulating tape 4 are connected by a thin metal wire 6, whereby the semiconductor element 1 and conductive wiring And 2 are electrically connected.

The sealing resin 7 is composed of the semiconductor element 1 and the thin metal wires 6.
And the semiconductor element fixing surface 4a of the insulating tape.

In the sixth embodiment, the distance c from the side surface of the semiconductor element 1 to the side surface of the sealing resin 7 is set to the external terminal 8
The distance between them is set to be equal to or more than d so that the external terminals 8 can be arranged not only inside the lower surface of the semiconductor element 1 but also outside the lower surface of the semiconductor element 1. That is, the external terminal 8 is also arranged between the side surface of the semiconductor element 1 and the side surface of the sealing resin 7 and on the mounting surface side of the semiconductor device.

By arranging the external terminals 8 also outside the lower surface of the semiconductor element 1 in this way, when the semiconductor device is mounted on a substrate, the external terminals 8 located outside the surface of the semiconductor element 1 are the same as those of the semiconductor device. It comes to restrain the deformation.

As a result, of the strains generated in the external terminals located in the plane of the semiconductor element, the strain component due to the warp deformation of the semiconductor device is reduced, so that the breakage of the external terminals 8 can be prevented.

Therefore, the breakage of the conductive wiring and the breakage of the external terminals can be suppressed, and a highly reliable BGA type semiconductor device can be realized.

As a seventh embodiment of the present invention, the dummy wiring 10 is not provided in the first embodiment described above,
In some cases, the conductive wiring 2 has a width a inside the insulating film 3 that is wider than a width b outside the insulating film 3, and this width outside gradually decreases to a constant value.

That is, this is an example in which only the dummy wiring 10 is excluded from the land 2b in the example shown in FIG.

Also according to the seventh embodiment, it is possible to increase the function of reducing the amount of thermal deformation of the insulating film 3 itself in the vicinity of the conductive wiring 2 by restraining the conductive wiring 2, and disconnection of the conductive wiring. And a highly reliable BGA type semiconductor device can be realized.

[0138]

Since the present invention is constructed as described above, it has the following effects. It is possible to reduce the amount of deformation of the insulating film when a temperature change is applied to the ball grid array type semiconductor device, and to reduce the amount of out-of-plane deformation of the semiconductor device to reduce the tensile load generated on the insulating tape. You can As a result, the stress generated at the lower end of the side surface of the insulating film can be reduced, so that it is possible to prevent the conductive wiring protruding from the insulating film from being broken.

Further, by reducing the deformation of the semiconductor device, it is possible to reduce the strain generated in the external terminal located at the end of the semiconductor element and prevent the external terminal from breaking.

Therefore, the breakage of the conductive wiring and the breakage of the external terminals can be suppressed, and a highly reliable BGA type semiconductor device can be realized.

[Brief description of drawings]

FIG. 1 is a plan view of a first embodiment of a semiconductor device according to the present invention.

FIG. 2 is a cross-sectional view of the semiconductor device shown in FIG.

FIG. 3 is a cross-sectional view showing another aspect of the first embodiment shown in FIG.

FIG. 4 is a plan view showing another mode of the first embodiment shown in FIG. 1 with the member on the upper portion of the insulating tape removed.

5 is a partial plan view showing another example of the conductive wiring shape of the semiconductor device according to the first embodiment shown in FIG. 1. FIG.

6 is a partial plan view showing still another example of the conductive wiring shape of the semiconductor device according to the first embodiment shown in FIG. 1. FIG.

FIG. 7 is a plan view of a second embodiment of a semiconductor device according to the present invention.

8 is a cross-sectional view of the semiconductor device shown in FIG.

9 is a partial plan view showing another aspect of the second embodiment shown in FIG. 7. FIG.

FIG. 10 is a partial plan view showing still another mode of the second embodiment shown in FIG.

FIG. 11 is a plan view of a third embodiment of a semiconductor device according to the present invention.

12 is a cross-sectional view of the semiconductor device shown in FIG.

FIG. 13 is a sectional view of a semiconductor device according to a fourth embodiment of the present invention.

FIG. 14 is a plan view of the semiconductor device shown in FIG.

FIG. 15 is a sectional view of a fifth embodiment of a semiconductor device according to the present invention.

16 is a plan view of the semiconductor device shown in FIG.

FIG. 17 is a sectional view of a semiconductor device according to a sixth embodiment of the present invention.

FIG. 18 is a cross-sectional view for explaining a conventional ball grid array type semiconductor device.

[Explanation of symbols]

1 Semiconductor element 2 Conductive wiring 2a Bonding pad 2b land 3 insulating film 3a Insulating film opening of bonding pad 3b Side of insulating film 4 Insulating tape 4a Surface of semiconductor tape to which insulating tape is fixed 4b Mounting surface of insulating tape 5 Adhesive members 6 thin metal wires 7 Sealing resin 8 external terminals 9 Insulating tape openings 10 Dummy wiring 11 protrusions 12 Insulation film openings 13 slits 14 Deformation restraint member

   ─────────────────────────────────────────────────── ─── Continued front page    (72) Inventor Masahiro Ichitani             5-20, Kamimizuhonmachi, Kodaira-shi, Tokyo             Hitachi Ltd. Semiconductor Division (72) Inventor Naonaka Tanaka             502 Kintatemachi, Tsuchiura City, Ibaraki Japan             Tate Seisakusho Mechanical Research Center

Claims (16)

[Claims] 1. In a ball grid array type semiconductor device, a plurality of pads and a plurality of lands, and a plurality of insulating films formed so as to cover each of the plurality of lands at least in a plane of a semiconductor element and are separated from each other. An insulating tape having a plurality of conductive members extending from each of the plurality of lands and protruding from the insulating film, and fixed to the surface of the insulating tape by an adhesive member,
A rectangular semiconductor element electrically connected to the conductive member through the pad by a thin metal wire, and a sealing resin that seals the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape. A ball grid array type semiconductor device, comprising: an external terminal joined to the land. 2. The ball grid array type semiconductor device according to claim 1, wherein at least one conductive member is selected from a plurality of conductive members extending from each of the plurality of lands and protruding from the insulating film. A ball grid array type semiconductor device, characterized in that it is electrically connected to the semiconductor element, and another conductive member is formed at a position at least sandwiching the electrically connected conductive member. 3. The ball grid array type semiconductor device according to claim 2, wherein the center point is a center of rotation with respect to a straight line connecting the center point of one land to the electrically conductive member to be electrically connected. , 90 ° on one side of the straight line
Forming at least one other conductive member in the rotated region, and forming at least one other conductive member in the region rotated 90 ° to the other side of the straight line. A characteristic ball grid array type semiconductor device. 4. The ball grid array type semiconductor device according to claim 1, wherein a width of the conductive member protruding from the insulating film inside the insulating film is made wider than a width outside the insulating film. Ball grid array type semiconductor device. 5. A ball grid array type semiconductor device comprising: a conductive wiring; a land on which a pad and a projection connected to the conductive wiring are formed; an insulating tape having the conductive wiring and an insulating film; Fixed on the surface of the insulating tape with an adhesive member,
A rectangular semiconductor element electrically connected to the conductive wiring by a thin metal wire, a sealing resin that seals the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and is bonded to the land. A ball grid array type semiconductor device, comprising: 6. A plurality of pads and a plurality of lands, an insulating film that covers the plurality of lands at least in the plane of the semiconductor element, an insulating tape having a conductive wiring connected to the pads and the lands, A rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape are sealed. In a ball grid array type semiconductor device having a sealing resin for stopping and an external terminal bonded to the land, the insulating film is a plurality of insulating films separated from each other, and each insulating film is an individual insulating film. The ball grid array type semiconductor is characterized in that it is formed so as to cover the above-mentioned land and a protrusion protruding from the insulating film is formed at the above-mentioned land. apparatus. 7. The ball grid array type semiconductor device according to claim 6, wherein a plurality of protrusions are formed on the land and are formed at least at positions sandwiching the conductive wiring. apparatus. 8. The ball grid array type semiconductor device according to claim 7, wherein one of the straight lines is one of the straight lines connecting the center point of one land to the conductive wiring and having the center point as the center of rotation. A ball, characterized in that at least one of the protrusions is formed in a region rotated by 90 ° to the side, and at least one protrusion is formed in a region rotated by 90 ° to the other side of the straight line. Grid array type semiconductor device. 9. The ball grid array type semiconductor device according to claim 5, wherein the width of the conductive wiring connected to the land inside the insulating film is wider than the width outside the insulating film. A ball grid array type semiconductor device characterized by: 10. A ball grid array type semiconductor device having a plurality of conductive wirings, a plurality of pads and lands connected to the conductive wirings, an insulating film, and a slit formed on the board mounting surface side. Insulating tape, fixed to the surface of the insulating tape by an adhesive member,
A rectangular semiconductor element electrically connected to the conductive wiring by a thin metal wire, a sealing resin that seals the periphery of the semiconductor element and a semiconductor element fixing surface of the insulating tape, and is bonded to the land. And a ball grid array type semiconductor device, comprising: 11. A ball grid array type semiconductor device, comprising: a conductive wiring, a pad and a land connected to the conductive wiring, and an insulating film formed so as to cover at least an outer peripheral portion of the land. The tape and the surface of the above-mentioned insulating tape are fixed by an adhesive member,
A rectangular semiconductor element electrically connected to the conductive wiring by a thin metal wire, a sealing resin that seals the periphery of the semiconductor element and a semiconductor element fixing surface of the insulating tape, and is bonded to the land. And a ball grid array type semiconductor device, comprising: 12. A conductive wire, a pad and a land connected to the conductive wire, an insulating tape having an insulating film, and an adhesive member secured to the surface of the insulating tape to form the conductive wire. A rectangular semiconductor element electrically connected by a thin metal wire, a sealing resin that seals the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and an external terminal joined to the land, In the ball grid array type semiconductor device having the above-mentioned, the linear expansion coefficient of the sealing resin is equal to the linear expansion coefficient of the insulating tape. 13. A conductive wire, a pad and a land connected to the conductive wire, an insulating tape having an insulating film, and an adhesive member fixed to the surface of the insulating tape to form the conductive wire. A rectangular semiconductor element electrically connected by a thin metal wire, a sealing resin that seals the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and an external terminal joined to the land, In the ball grid array type semiconductor device having the above-mentioned, the linear expansion coefficient of the insulating film is equal to the linear expansion coefficient of the adhesive member. 14. A ball grid array type semiconductor device, comprising: conductive wiring, pads and lands connected to the conductive wiring, an insulating tape having an insulating film, and an adhesive member on the surface of the insulating tape. Fixed,
A rectangular semiconductor element electrically connected to the conductive wiring, a deformation restraint member formed on the surface of the insulating tape, the semiconductor element and the periphery of the deformation restraint member, and the semiconductor element fixed to the insulating tape. A ball grid array type semiconductor device, comprising: a sealing resin that seals the surface; and an external terminal that is bonded to the land. 15. A plurality of conductive wires, a plurality of pads and lands connected to the conductive wires, an insulating tape having an insulating film, and a metal fixed to the surface of the insulating tape by an adhesive member. A rectangular semiconductor element that is electrically connected to the conductive wiring by a thin wire, a sealing resin that seals the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape, and is bonded to the land. In a ball grid array type semiconductor device having a plurality of external terminals, the distance from the semiconductor element side surface to the sealing resin side surface is equal to or more than the interval between the external terminals, at least,
Between the semiconductor element side surface to the sealing resin side surface,
A ball grid array type semiconductor device characterized in that the external terminals are arranged. 16. A plurality of pads and a plurality of lands, an insulating film that covers the plurality of lands at least in the plane of the semiconductor element, an insulating tape having a conductive wiring connected to the pads and the lands, A rectangular semiconductor element fixed to the surface of the insulating tape by an adhesive member and electrically connected to the conductive wiring by a fine metal wire, and the periphery of the semiconductor element and the semiconductor element fixing surface of the insulating tape are sealed. In a ball grid array type semiconductor device having a sealing resin for stopping and an external terminal bonded to the land, the insulating film is a plurality of insulating films separated from each other, and each insulating film is an individual insulating film. The conductive wiring that is formed so as to cover the land and is connected to the land has a width inside the insulating film wider than that outside the insulating film. Ball grid array type semiconductor device.