Abstract:
A chip package structure is provided. The chip package structure comprises a first substrate, a second substrate and a plurality of chips. Therein, one of the chips is connected to the first substrate and electrically connected to the first substrate through a via hole of the first substrate. Thereby, the second substrate does not need the via hole for electrical connection of chips and thus, the surface thereof is adapted to remain intact to allow for the disposition of conductive balls throughout the surface.

Description:
[0001]    This application claims priority to Taiwan Patent Application No. 097109741 filed on Mar. 19, 2008, the disclosures of which are incorporated herein by reference in their entirety. 
       CROSS-REFERENCES TO RELATED APPLICATIONS 
       [0002]    Not applicable. 
       BACKGROUND OF THE INVENTION 
       [0003]    1. Field of the Invention 
         [0004]    The present invention relates to a chip package structure, and more particularly, relates to a chip package structure adopting package on package (PoP) technology. 
         [0005]    2. Descriptions of the Related Art 
         [0006]    Because electronic products have become miniaturized, the internal space in such electronic products has become increasingly smaller. Hence, almost all manufacturers are directing efforts into shrinking the dimensions of the internal elements in the electronic products. The arrangement of chips in smaller space has also become important with regards to integration. According to the package on package (PoP) technology, a plurality of chips are stacked on each other in a single chip package structure, so that a plurality of chips are packaged with the area of the package remaining unchanged. With the PoP technology, the area occupied by the plurality of chips is reduced remarkably only at a cost of a slightly increased thickness of the chip package structure. For this reason, the PoP technology has gradually found wide application in various electronic products. 
         [0007]    However, packaging a plurality of chips into a single chip package structure leads to a significant increase of the number of pins in the single chip package structure for connection with other electronic devices, such as printed circuit boards (PCBs). Therefore, in a conventional chip package structure  1  as shown in  FIG. 1 , a Ball Grid Array (BGA) packaging technology for disposing a plurality of conductive balls  15  on a surface of a substrate  101  is adopted together as a means to increase the number of pins (i.e., conductive balls) for electrical connection. 
         [0008]    The conventional chip package structure  1  comprises a single substrate  101 , a first chip  111 , a second chip  112 , a plurality of conductive balls  15 , a first wire portion  121 , a second wire portion  122 , a first adhesive layer  131 , a second adhesive layer  132 , a plastic layer  141  and an outer plastic layer  144 . A first bonding surface  111   a  of the first chip  111  is partially adhered to a second surface  101   b  of the substrate  101  by means of the first adhesive layer  131 , and is electrically connected to a first surface  101   a  of the substrate  101  by means of the first wire portion  121  which passes through a via hole  101   c  of the substrate  101 . The plastic layer  141  is formed in the via hole  101   c  and partially covers the surface  101   a  of the substrate  101  to protect the first wire portion  121  and to facilitate the packaging process. A second opposite surface  112   b  of the second chip  112  is adhered to a first opposite surface  111   b  of the first chip by means of the second adhesive layer  132 . A second bonding surface  112   a  of the second chip  112  is electrically connected to the second surface  101   b  of the substrate  101  via the second wire portion  122 . Finally, the structure is covered by the outer plastic layer  144 . 
         [0009]    The plurality of conductive balls  15  must be kept off the via hole  101   c  and the plastic layer  141 , so they can only be disposed on the remaining portions of the first surface  101   a  of the substrate  101 . To package a plurality of chips, the substrate  101  is formed with the via hole  101   c , so that the first wire portion  121  passes through the via hole  101  to electrically connect the first chip  111  to the substrate  101  without interfering with the second wire portion  122  for electrically connecting the second chip  112  to the substrate  101 . Hence, it is impossible for the plurality of conductive balls  15  to be disposed throughout the first surface  101   a  of the substrate  101 , which decreases the allowed number of conductive balls  15 . 
         [0010]    In summary, the PoP technology used at present for the BGA package fails to meet the demand of increasing the number of pins by effectively increasing the number of conductive balls. In view of this, it is highly desirable in the art to provide a chip package structure capable of packaging a plurality of chips and remarkably increasing the number of conductive balls. 
       SUMMARY OF THE INVENTION 
       [0011]    One objective of this invention is to provide a chip package structure comprising a plurality of chips. The chip package structure packages the plurality of chips at the same time and eliminates the need of a via hole on a surface of a substrate where a plurality of conductive balls are disposed to meet the demand of increasing the number of pins of the chip package structure. In addition, more chips may be stacked while the occupied area remains unchanged. 
         [0012]    The chip package structure of this invention comprises a first substrate, a second substrate and a plurality of chips. The first substrate and the second substrate are used to package the plurality of chips with the PoP technology, wherein one of the plurality of chips is connected to the first substrate and electrically connected to the first substrate through a via hole of the first substrate, while the other chips are connected to other positions and electrically connected to the first substrate and the second substrate. Because the via hole for electrically connecting the chips is eliminated in the second substrate, the surface of the second substrate remains intact and the conductive balls are allowed to be distributed throughout the entire surface thereof without a via hole as occurred in the prior art solutions. 
         [0013]    The detailed technology and preferred embodiments implemented for the subject invention are described in the following paragraphs accompanying the appended drawings for people skilled in this field to well appreciate the features of the claimed invention. 
     
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         [0014]      FIG. 1  is a schematic cross-sectional view of the conventional chip package structure adopting the PoP technology; 
           [0015]      FIG. 2  is a schematic cross-sectional view of the first embodiment of a chip package structure according to this invention; 
           [0016]      FIG. 3  is a schematic cross-sectional view of the second embodiment of the chip package structure according to this invention; 
           [0017]      FIG. 4  is a schematic cross-sectional view of the third embodiment of the chip package structure according to this invention; 
           [0018]      FIG. 5  is a schematic cross-sectional view of the fourth embodiment of the chip package structure according to this invention; and 
           [0019]      FIGS. 6A to 6H  are schematic cross-sectional view partially illustrating a manufacturing process flow of the chip package structure according to this invention. 
       
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENT 
       [0020]    The basic concept of the chip package structure of this invention is that by using two substrates, a plurality of chips are packaged with the PoP technology in such a way that a via hole, which is conventionally used for electrically connecting the chips, is eliminated in one of the two substrates. As a result, one substrate remains intact while the conductive balls are allowed to be distributed throughout the entire surface thereof without the via hole. Accordingly, when the Ball Grid Array (BGA) packaging technology is adopted, the number of conductive balls may be increased significantly to meet the demand for increasing the number of pins in the chip package structure without changing the occupied area. 
         [0021]    As shown in  FIG. 2 , a chip package structure  2  of this invention generally at least comprises a first substrate  201 , a second substrate  202 , a plurality of chips, a first wire portion  221 , a second wire portion  222 , a third wire portion  223 , a fourth wire portion  224 , a first adhesive layer  231 , a second adhesive layer  232 , a third adhesive layer  233 , a fourth adhesive layer  234 , a first plastic layer  241  and a second plastic layer  242 . The plurality of chips includes a first chip  211 , a second chip  212 , and a third chip  213 . The first substrate  201  has a first surface  201   a , a second surface  201   b  and a via hole  201   c . The second substrate  202  has a third surface  202   a , a fourth surface  202   b  and a plurality of conductive balls  25 . The first chip  211  has a first bonding surface  211   a  and a first opposite surface  211   b . The second chip  212  has a second bonding surface  212   a  and a second opposite surface  212   b . The third chip  213  has a third bonding surface  213   a  and a third opposite surface  213   b.    
         [0022]    Generally speaking, the first chip  211  covers the via hole  201   c  of the first substrate  201 . The wires pass through the via hole  201   c  and electrically connected to the first surface  201   a  of the first substrate  201  via pads. Also, the first chip  211  is connected to the second surface  201   b  of the first substrate  201  via an adhesive layer. The third surface  202   a  of the second substrate  202  is opposite to and connects with one of the first surface  201   a  and the second surface  201   b  of the first substrate  201 . The other of the first surface  201   a  and the second surface  201   b  is in turn electrically connected to the third surface  202   a  via wires and pads. Hence, the conductive balls  25  can be distributed throughout the fourth surface  202   b  of the second substrate  202 . As a result, the number of pins is increased. However, the number of conductive balls  15  in the conventional chip package structure  1  has to be decreased due to the vial hole  101   c  of the substrate  101  (as shown in  FIG. 1 ). Finally, all the devices above the second substrate  202  are covered by an outer plastic layer  244  to protect the whole chip package structure  2 . 
         [0023]    The first embodiment of this invention is just as shown in  FIG. 2 . In the chip package structure  2  of this invention, the second surface  201   b  of the first substrate  201  is opposite the third surface  202   a  of the second substrate  202 . The first bonding surface  211   a  of the first chip  211  is connected to the second surface  201   b  of the first substrate  201  via the first adhesive layer  231 , and covers the via hole  201   c  of the first substrate  201 . Additionally, the first wire portion  221  passes through the via hole  201   c  to electrically connect the first bonding surface  211   a  of the first chip  211  to the first surface  201   a  of the first substrate  201 . 
         [0024]    The first plastic layer  241  covers the first chip  211 , and is disposed between the second adhesive layer  232  on the third surface  202   a  of the second substrate  202  and the first substrate  201 . The first plastic layer  241  is adapted to connect the second adhesive layer  232  and the second surface  201   b  of the first substrate  201 . In other words, the first substrate  201  and the second substrate  202  are connected and fixed together via the first plastic layer  241  and the second adhesive layer  232 . 
         [0025]    The second plastic layer  242  is filled and disposed in the via hole  201   c  and partially covers the first surface  201   a  of the first substrate  201 . In addition to the second plastic layer  242 , the third adhesive layer  233  and the second chip  212  are also disposed above the first substrate  201  in sequence. 
         [0026]    More specifically, the third adhesive layer  233  is adapted to adhere the second plastic layer  242  above the first substrate  201  to the second opposite surface  212   b  of the second chip  212 . On the other hand, the second plastic layer  242  is disposed at least between the third adhesive layer  233  and the first substrate  201  and thus is adapted to connect the third adhesive layer  233  and the first surface  201   a . By connecting the second opposite surface  212   b  of the second chip  212  and the first surface  201   a  of the first substrate  201  via the third adhesive layer  233  and the second plastic layer  242 , the second chip  212  and the first substrate  201  are connected together. Additionally, the second bonding surface  212   a  of the second chip  212  is electrically connected with the first surface  201   a  of the first substrate  201  via the third wire portion  223 . 
         [0027]    The third opposite surface  213   b  of the third chip  213  and the first opposite surface  211   b  of the first chip  211  are connected to each other via the fourth adhesive layer  234 . On the other hand, the third bonding surface  213   a  of the third chip  213  adjoins and is covered by the first plastic layer  241 . Additionally, the third bonding surface  213   a  of the third chip  213  is further electrically connected to the second surface  201   b  of the first substrate  201  via the fourth wire portion  224  of the chip package structure  2 . In this embodiment, the chip package structure  2  comprises the third chip  213 . However, in other embodiments, the chip package structure  2  may not comprise the third chip  213 , or may even comprise chips arranged in other manners. 
         [0028]    The first substrate  201  is not only connected and adhered to the second substrate  202  via the first plastic layer  241  and the second adhesive layer  232 , but the first surface  201   a  of the first substrate  201  is also electrically connected to the third surface  202   a  of the second substrate  202  via the second wire portion  222 . Thus, the structures (exclusive of the wires) above the third surface  202   a  of the second substrate  202  include, from top to bottom, the second chip  212 , the third adhesive layer  233 , the second plastic layer  242 , the first substrate  201 , the first adhesive layer  231 , the first chip  211 , the fourth adhesive layer  234 , the third chip  213 , the first plastic layer  241 , and the second adhesive layer  232 , in which the first plastic layer  241  is disposed under the first substrate  201 , the first adhesive layer  231 , the first chip  211 , the fourth adhesive layer  234  and the third chip  213  but above the second adhesive layer  232 . Finally, the structures above the third surface  202   a  of the second substrate  202  is covered by the outer plastic layer  244  to avoid exposure of the wires, chips and substrates, thus forming a complete package. 
         [0029]    The plurality of conductive balls  25  is disposed underneath the fourth surface  202   b  of the second substrate  202 . The first chip  211  is electrically connected to the corresponding conductive balls  25  via the first wire portion  221 , the first substrate  201 , the second wire portion  222  and the second substrate  202 . Likewise, the second chip  212  is electrically connected to corresponding conductive balls  25  via the third wire portion  223 , the first substrate  201 , the second wire portion  222  and the second substrate  202 . Similarly, the third chip  213  is electrically connected to the corresponding conductive balls  25  via the fourth wire portion  224 , the first substrate  201 , the second wire portion  222  and the second substrate  202 . 
         [0030]    The second embodiment of this invention is depicted in  FIG. 3 . A chip package structure  3  of this embodiment consists of the same elements as those of the chip package structure  2  of the first embodiment, except that the relative positions of some elements are reversed from those of the first embodiment in the vertical direction. Except the wires, the third chip  213 , the fourth adhesive layer  234 , the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233  and the second chip  212  of this embodiment are arranged in a reversed order from that of the first embodiment. 
         [0031]    More specifically, in this embodiment, the third surface  202   a  of the second substrate  202  of the chip package structure  3  is opposite the first surface  201   a  of the first substrate  201  (instead of the second surface  201   b  of the first substrate  201 ), and the second surface  201   b  (instead of the first surface  201   a ) is electrically connected to the third surface  202   a  via the second wire portion  222 . 
         [0032]    In other words, positions of the first chip  211 , the second chip  212 , the third chip  213 , the first wire portion  221 , the third wire portion  223 , the fourth wire portion  224 , the first adhesive layer  231 , the third adhesive layer  233 , the fourth adhesive layer  234  and the second plastic layer  242  relative to the first substrate  201  are all in the same positions as those of the first embodiment. Furthermore, the plurality of conductive balls  25  is also disposed on the fourth surface  202   b  of the second substrate. 
         [0033]    Compared to the chip package structure of the first embodiment, the chip package structure  3  of the second embodiment is unique in that elements connected to the first substrate  201  are arranged in a reversed order from that of the second substrate  202  and are connected to the second substrate  202 . Hence, the second wire portion  222  is adapted to electrically connect the top surface (i.e., the second surface  201   b  in this embodiment) of the first substrate  201  and the second substrate  202 . Similarly, the first plastic layer  241  is also disposed between the first substrate  201  and the second substrate  202 , and the second adhesive layer  232  is adapted to adhere the first plastic layer  241  to the third surface  202   a  of the second substrate  202 . However, the first plastic layer  241  covers the second chip  212 , and the second adhesive layer  232  is adapted to connect the first surface  201   a  of the first substrate  201  and the third surface  202   a  of the second substrate  202  together (instead of connecting the second surface  201   b  and the third surface  202   a  together). 
         [0034]    Other structures of this embodiment are identical to the first embodiment and thus, will not be described again herein. As thus, the structures (exclusive of the wires) in the chip package structure  3  of this embodiment include, from top to bottom, the outer plastic layer  244 , the third chip  213 , the fourth adhesive layer  234 , the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233 , the second chip  212 , the first plastic layer  241 , the second adhesive layer  232  and the second substrate  202 . 
         [0035]    The third embodiment of this invention is depicted in  FIG. 4 . In this embodiment, a chip package structure  4  comprises at least a first substrate  201 , a second substrate  202 , a plurality of chips, a first wire portion  221 , a second wire portion  222 , a third wire portion  223 , a fifth wire portion  225 , a first adhesive layer  231 , a second adhesive layer  232 , a third adhesive layer  233 , a fifth adhesive layer  235 , a first plastic layer  241 , a second plastic layer  242 , a third plastic layer  243  and an outer plastic layer  244 . The plurality of chips comprises a first chip  211 , a second chip  212  and a fourth chip  214 . The first substrate  201  has a first surface  201   a , a second surface  201   b  and a via hole  201   c . The second substrate  202  comprises a third surface  202   a , a fourth surface  202   b  and a plurality of conductive balls  25 . The first chip  211  comprises a first bonding surface  211   a  and a first opposite surface  211   b . The second chip  212  has a second bonding surface  212   a  and a second opposite surface  212   b . The fourth chip  214  has a fourth bonding surface  214   a  and a fourth opposite surface  214   b.    
         [0036]    That is, the chip package structure  4  is similar to the chip package structure  2  of the first embodiment, but does not include the third chip  213 , the fourth adhesive layer  234  for adhering the third chip  213  to the first substrate  201 , and the fourth wire portion  224  for electrically connecting the third chip  213  to the first substrate  201  in the chip package structure  2  of the first embodiment. Also, as compared to the chip package structure  2  of the first embodiment, the chip package structure  4  of the third embodiment further comprises the fourth chip  214 , the fifth wire portion  225 , the fifth adhesive layer  235  and the third plastic layer  243 . 
         [0037]    Here, the relative positions among the first substrate  201 , the first chip  211 , the second chip  212 , the first wire portion  221 , the second wire portion  222 , the third wire portion  223 , the first adhesive layer  231 , the third adhesive layer  233 , and the second plastic layer  242  are just the same as those of the chip package structure  2  of the first embodiment and thus, will not be described again herein. 
         [0038]    The fourth opposite surface  214   b  of the fourth chip  214  and the third surface  202   a  of the second substrate  202  are connected to each other via the fifth adhesive layer  235 . Furthermore, the fourth bonding surface  214   a  of the fourth chip  214  is further electrically connected to the third surface  202   a  of the second substrate  202  via the fifth wire portion  225 , so that the fourth chip  214  is electrically connected, via the fifth wire portion  225  and the second substrate  202 , to a plurality of corresponding conductive balls  25  disposed on the fourth surface  202   b  of the second substrate  202 . 
         [0039]    On the other hand, the fourth bonding surface  214   a  of the fourth chip  214  adjoins the third plastic layer  243 . The third plastic layer  243  is adapted to cover the fourth chip  214 , the fifth adhesive layer  235  and the fifth wire portion  225 . The second adhesive layer  232  is disposed above the third plastic layer  243 , i.e., the third plastic layer  243  is disposed between the second adhesive layer  232  and the second substrate  202  and connects the second adhesive layer  232  and the third surface  202   a  of the second substrate  202 . 
         [0040]    In the chip package structure  4  of the third embodiment, via the second adhesive layer  232 , the structure formed by the first substrate  201 , the first chip  211 , the second chip  212 , the first wire portion  221 , the third wire portion  223 , the first adhesive layer  231 , the third adhesive layer  233  and the second plastic layer  242  similar to those of the first embodiment can be connected to the third plastic layer  243 . 
         [0041]    Similar to the first embodiment, the second surface  201   b  of the first substrate  201  is opposite to and connected to the third surface  202   a  of the second substrate  202 , and the first surface  201   a  of the first substrate  201  is electrically connected to the third surface  202   a  of the second substrate  202  via the second wire portion  222 . As thus, the structures (exclusive of the wires) above the third surface  202   a  of the second substrate  202  include, from top to bottom, the second chip  212 , the third adhesive layer  233 , the second plastic layer  242 , the first substrate  201 , the first adhesive layer  231 , the first chip  211 , the first plastic layer  241 , the second adhesive layer  232 , the third plastic layer  243 , the fourth chip  214  and the fifth adhesive layer  235 . The first plastic layer  241  is disposed under the first substrate  201 , the first adhesive layer  231 , the first chip  211 , but above the second adhesive layer  232 . The third plastic layer  243  is disposed under the second adhesive layer  232  but above the fourth chip  214 , the fifth adhesive layer  235  and the second substrate  202 . Finally, the structures above the third surface  202   a  of the second substrate  202  is covered by the outer plastic layer  244  to prevent the exposure of the wires, chips and substrates, thus forming a complete package. 
         [0042]    The fourth embodiment of this invention is a chip package structure  5 , a schematic cross-sectional view of which is depicted in  FIG. 5 . The chip package stricture  5  consists of the same elements as those of the chip package structure  3  of the third embodiment, except that the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233  and the second chip  212  of this embodiment are arranged in reverse order from that of the third embodiment. 
         [0043]    The relative positions among the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233  and the second chip  212  are all similar to those of the second embodiment. Furthermore, in the chip package structure  5  of this embodiment, the first surface  201   a  (instead of the second surface  201   b ) of the first substrate  201  is opposite to the third surface  202   a  of the second substrate  202 , and the second surface  201   b  (instead of the first surface  201   a ) of the first substrate  201  is electrically connected to the third surface  202   a  via the second wire portion  222 . 
         [0044]    Like the third embodiment but unlike the second embodiment, the chip package structure  5  of the fourth embodiment comprises the fourth chip  214 , the fifth wire portion  225 , the fifth adhesive layer  235  and the third plastic layer  243 , but does not comprises the third chip  213 , the fourth wire portion  224  and the fourth adhesive layer  234 . 
         [0045]    In the chip package structure  5  of this embodiment, elements above the second adhesive layer  232  as well as the relative positions thereof are the same as those of the second embodiment, and elements under the third plastic layer  243  as well as the relative positions thereof are the same as those of the third embodiment. Thus, this will not be described again herein. As thus, the structures (exclusive of the wires) in the chip package structure  5  of this embodiment include, from top to bottom, the outer plastic layer  244 , the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233 , the second chip  212 , the first plastic layer  241 , the second adhesive layer  232 , the third plastic layer  243 , the fourth chip  214 , the fifth adhesive layer  235  and the second substrate  202 . 
         [0046]    The materials of the individual elements in the above embodiments will be detailed as follows. The conductive balls are preferably made of a material comprising tin. Other conductive materials adapted to be connected to the second substrate may also be used in this invention. The first adhesive layer for connecting the first chip to the first substrate is preferably made of a B-stage thermosetting mixture. Other adhesive layers, i.e., the second, the third, the fourth and the fifth adhesive layers, may be made of an adhesive film or an adhesive with epoxy resin. 
         [0047]    The schematic cross-sectional views illustrate a manufacturing process flow partially using the chip package structure  2  of the first embodiment of this invention as an example.  FIGS. 6A to 6H  illustrate the flow diagrams of connecting and electronically connecting the first chip  211 , the second chip  212 , the first substrate  201 , the second substrate  202  and a plurality of conductive balls  25  with each other. Initially, as shown in  FIG. 6A , the first bonding surface  211   a  of the first chip  211  is adhered to the second surface  201   b  of the first substrate  201  via the first adhesive layer  231 . The first chip  211  is adapted to cover the via hole  201   c  of the first substrate  201 . Subsequently, as shown in  FIG. 6B , the first plastic layer  241  is formed on the second surface  201   b  and covers the first chip  211 . Then, the resulting structure is flipped over with the first surface  201   a  facing upwards, as shown in  FIG. 6C . 
         [0048]    As shown in  FIG. 6D , the first wire portion  221  which passes through the via hole  201   c  is wire bonded to the first bonding surface  211   a  of the first chip  211  and the first surface  201   a  of the first substrate  201  to electrically connect the first bonding surface  211   a  and the first surface  201   a . Next, a second plastic layer  242  is partially formed on the first surface  201   a  of the first substrate  201  and in the through-hole  201   c  of the first substrate  201 , as shown in  FIG. 6E . Subsequently, as shown in  FIG. 6F , the first plastic layer  241  under the first substrate  201  is adhered to the third surface  202   a  of the second substrate  202  via the second adhesive layer  232 . The second opposite surface  212   b  of the second chip  212  is adhered to the second plastic layer  242  via the third adhesive layer  233  to connect the second chip  212  and the first substrate  201  together, as shown in  FIG. 6G . Finally, the second wire portion  222  is wire bonded to the first surface  201   a  of the first substrate  201  and the third surface  202   a  of the second substrate  202  to electrically connect the first substrate  201  and the second substrate  202 . The third wire portion  223  is wire bonded to the second bonding surface  212   a  of the second chip  212  and the first surface  201   a  of the first substrate  201  to electrically connect the second chip  212  and the first substrate  201 . Then, an outer plastic layer  244  is formed to cover the resulting structure, as shown in  FIG. 6H . The manufacturing process flows associated with other devices such as the third chip  213  and the fourth chip  214  will readily occur to those skilled in the art. 
         [0049]    In the above embodiments, some structures may be assembled and connected through the same process flow. For instance, the first chip  211 , the first adhesive layer  231 , the first substrate  201 , the second plastic layer  242 , the third adhesive layer  233  and the second chip  212  of the first to the fourth embodiments may be connected collectively at first, and then positioned in a normal orientation or upside down before being subjected to a subsequent adhering and packaging step to form the chip package structure of the respective embodiments. 
         [0050]    The chip package structure of the above embodiments may further have chips unlike the aforesaid ones packaged therein. All the chips from the first to the fourth may be included, or only the first chip and any one of the other chips described above may be included. Such variations and corresponding designs may readily occur to those skilled in the art and therefore, still fall within scope of the claims of this invention. 
         [0051]    The above disclosure is related to the detailed technical contents and inventive features thereof. People skilled in this field may proceed with a variety of modifications and replacements based on the disclosures and suggestions of the invention as described without departing from the characteristics thereof. Nevertheless, although such modifications and replacements are not fully disclosed in the above descriptions, they have substantially been covered in the following claims as appended.