Abstract:
A board comprises a cavity for placing an electronic component on a base, a pair of pads for mounting said electronic component, each of said pads is formed on said base, a pair of through holes piercing through said board from said base, each of said through holes includes a land, and wires which electrically connect said lands and said pads, respectively.

Description:
BACKGROUND OF THE INVENTION 
     A present invention relates to a wiring board and a method of manufacturing a wiring board, and relates in particular to the wiring board and the method of manufacturing the wiring board for improving the reliability of component connections. 
     A decoupling capacitor must usually be placed around the LSI in order to reduce the power supply noise that accompanies high-speed LSI operation. Recently typical wiring boards are even formed with a cavity containing a component (capacitor, etc.). On this type of wiring board, the cavity must be formed on the surface of the wiring board corresponding to the rear side of the LSI so that the distance between the LSI and capacitor must be kept as short as possible. 
     A technology characterized in that “the capacitor terminal electrode and the inner through hole within the cavity, or the exposed section of the through hole are connected” is disclosed in the Laid-Open Hei No. 2004-342641. In other words, the terminal electrode and inner through hole or through hole form a pair. 
     A cavity forming technique is disclosed for example in Laid-Open Hei No. 10-22643. This technology is capable of highly accurate control along the Z-axis by utilizing a numerically controlled machine tool to electrically detect contact between the machining drill and the wiring board. This technology is related technology capable forming a cavity on the wiring board of the present invention. 
     SUMMARY OF THE INVENTION 
     In the technology disclosed in the Laid-Open Hei No. 2004-342641, it is necessary that the position of the inner through hole or the through hole matches the position of the terminal electrode of the capacitor. An electrode dimension of the low ESL capacitor recently is substantially 0.3 mm pitch or 0.2 mm pitch. However, forming the through hole at 0.3 mm pitch or 0.2 mm pitch is extremely difficult and even supposing that forming the through hole at this narrow pitch is possible, the through hole itself must be made smaller. Making the through hole smaller reduces the area to be contacted with the electrode of the capacitor, and lowers the reliability of connections such as soldered connections. 
     In the technology disclosed in the Laid-Open Hei No. 2004-342641, the electrode of the capacitor is mounted on the land of the through hole. The size of the land is not enough for mounting the electrode of the capacitor. So, the reliability of the connection between the electrode and the land is decreased. It is a problem of the technology disclosed in the Laid-Open Hei No. 2004-342641. 
     The object of the present invention is to provide a wiring board and a method of manufacturing wiring board for resolving the above mentioned problem. 
     A board comprises a cavity for placing an electronic component on a base, a pair of pads for mounting said electronic component, each of said pads is formed on said base, a pair of through holes piercing through said board from said base, each of said through holes includes a land, and wires which electrically connect said lands and said pads, respectively. 
     A board comprises a cavity for placing an electronic component on a base, a pair of through holes piercing through said board from said base, a distance between said through holes fits within said cavity and is substantially minimum to make said through holes, a pair of pads for mounting said electronic component, a pitch of said electronic component is shorter than said distance, and wires which electrically connects lands of said through holes and said pads, respectively. 
     A method of manufacturing a board comprises forming a pair of through holes including land, a pair of pads for mounting a component, and wires for electrically connecting said pad and said land, in the inner layer of said board, forming a cavity for exposing said pad, coating said pad with a first plating of low solder wettability, coating said coated pad with a second plating of high solder wettability, and removing said second plating coating with said land and said wire. 
     A method of manufacturing a board comprises forming a pair of through holes including land, a pair of pads for mounting a component, and wires for electrically connecting said pad and said land, in the inner layer of said board, forming a first cavity for exposing said pad, coating said pad with a first plating of low solder wettability, coating said coated pad with a second plating of high solder wettability, and forming a second cavity for exposing said land and said wire. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
       Other features and advantages of the invention will be made more apparent by the following detailed description and the accompanying drawings, wherein: 
         FIG. 1A  is a drawing showing the wiring board of a first exemplary embodiment of the present invention; 
         FIG. 1B  is a drawing showing the wiring board of the first exemplary embodiment of the present invention; 
         FIG. 2A  is a drawing showing the solder wicking on the wiring board; 
         FIG. 2B  is a drawing showing the solder wicking on the wiring board; 
         FIG. 3A  is a drawing for describing the method for forming the cavity of the wiring board of a second exemplary embodiment of the present invention; 
         FIG. 3B  is a drawing for describing the method for forming the cavity of the wiring board of the second exemplary embodiment of the present invention; 
         FIG. 4  is a flowchart for showing the manufacturing method of the second exemplary embodiment of the present invention; 
         FIG. 5A  is a drawing showing a third exemplary embodiment of the present invention; 
         FIG. 5B  is a drawing showing the third exemplary embodiment of the present invention; 
         FIG. 6  is a flow chart for describing the manufacturing method for the third exemplary embodiment of the present invention; 
         FIG. 7  is a drawing showing the wiring board of a fourth exemplary embodiment of the present invention; 
         FIG. 8  is a drawing showing the wiring board of a fifth exemplary embodiment of the present invention; 
         FIG. 9  is a drawing showing the wiring board of a sixth exemplary embodiment of the present invention; 
     
    
    
     In the drawings, the same reference numerals represent the same structural elements. 
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A first exemplary embodiment of the present invention is described referring to the drawings.  FIG. 1  is a structural view of the wiring board  20 , a cavity  29  of the first exemplary embodiment is formed on the wiring board  20 .  FIG. 1A  is a cross sectional view and  FIG. 1B  is a bottom view. 
     A wiring board  20  of the first exemplary embodiment as shown in  FIG. 1  includes a core layer  24 , a build layer  23 - 1 , and a build layer  23 - 2 . The core layer  24  includes an inner layer ground plane  31 , and an inner layer power supply plane  32 . 
     An LSI  10  is mounted on the upper surface (build layer  23 - 1 ) of the wiring board  20 . An external terminal  28  is mounted on the bottom surface (build layer  23 - 2 ) of the wiring board  20 . The cavity  29  is formed on the bottom side of the wiring board  20 . A mounting pad  30 - 1  and a mounting pad  30 - 2  for mounting a chip component  40  are formed within the cavity  29 . The chip component  40  is mounted on a base of the cavity  29 . The chip component is a capacitor, for example. 
     The mounting pad  30 - 1  is connected to the inner layer ground plane  31  via a wire  26 - 1  (for example, the short wire  26 - 1  is made of copper) and a through hole  25 - 1 . The mounting pad  30 - 2  is connected to the inner layer power supply plane  32  via a wire  26 - 2  (for example, the short wire  26 - 2  is made of copper) and a through hole  25 - 2 . The wires  26 - 1 ,  26 - 2  is short, for example, the length of the wires  26 - 1 ,  26 - 2  is within the range from 0.1 mm to 0.5 mm. The distance between the through holes  25 - 1  and the through hole  25 - 2  is slightly longer than the pitch of the electrode of the chip component. When the chip component is the capacitor, the pitch of the electrode of the capacitor is within the range from 0.2 mm to 0.3 mm, for example. So, in the case, the distance between the through hole  25 - 1  and the through hole  25 - 2  is slightly longer than the pitch of the electrode by the range from 0.1 mm to 0.5 mm, for example. However, the distance between the through hole  25 - 1  and the through hole  25 - 2  is not limited above mentioned distance. It is preferable that the distance between the through hole  25 - 1  and the through hole  25 - 2  is minimum distance for forming the wires  26 - 1 ,  26 - 2  between the through holes  25 - 1 ,  25 - 2  and the electrodes of the chip component. In other words, the wires  26 - 1  and  26 - 2  are formed in a length required for connecting the electrode of the chip component  40  and the through hole lands formed at a pitch longer than the pitch of the electrode of the chip component  40 . The length of the wires  26 - 1  and  26 - 2  is for example approximately 0.1 to 0.5 millimeters. However the length of the wires  26 - 1  and  26 - 2  is not limited to these dimensions. As shown in  FIG. 1B , the wires  26 - 2  and  26 - 2 , the mounting pads  30 - 1  and  30 - 2 , and the through holes  25 - 3  and  25 - 4  are aligned in substantially linearly. 
     A distance between the through hole  25 - 3  and the through hole  25 - 4  fits within the cavity  29 , and is substantially minimum to make the through holes  25 - 3 ,  25 - 4  in the size for remaining the high solderability. 
     The through hole  25 - 1  contains a through hole land  25 - 3  (for example, the through hole land  25 - 3  is made of copper). The through hole  25 - 2  contains a through hole land  25 - 4  (for example, the through hole land  25 - 4  is made of copper). The through hole land  25 - 3  and the through hole land  25 - 4  are separate from the mounting pad  30 - 1  and the mounting pad  30 - 2 , respectively. And, The through hole  25 - 3 ,  25 - 4  are not directly connected to the mounting pad  30 - 1  and the mounting pad  30 - 2 , respectively. In other words, the pitch of the through hole lands  25 - 3 ,  25 - 4  is longer than the pitch of the mounting pads  30 - 1 ,  30 - 2 . The wire  26 - 1  connects the mounting pad  30 - 1  and the through hole land  25 - 3 . The wire  26 - 2  connects the mounting pad  30 - 2  and the through hole land  25 - 4 . 
     Surface treatment performed on the surface of the mounting pad  30 - 1  and the mounting pad  30 - 2  may include, “non-electrolytic nickel plating and non-electrolytic gold plating”, “preflux coating (organic solderability preservatives)”, or “solder precoating”. 
     Here, the terms “non-electrolytic nickel plating and non-electrolytic gold plating” are described. The non-electrolytic nickel plating is utilized for the layer preventing cross-diffusion between copper and gold. The wiring board  20  is usually made of copper. The copper itself can be directly plated with gold, but immediately cross-diffuses when heat is applied. To prevent the cross-diffusion, non-electrolytic nickel plating is applied as an under-layer plating of good adhesiveness. Nickel tends to oxidize when exposed to air, and then, the solder wettability decreases. 
     Non-electrolytic gold plating has high solder wettability. And, non-electrolytic gold plating is used for making solder connections. Gold also has the advantages of being storable for long periods. And, gold has a heat-resistant compared to preflux (organic solderability preservatives). 
     It is possible to use other plating which has low solder wettability instead of non-electrolytic nickel plating. Also, it is possible to use other plating which has high solder wettability instead of non-electrolytic gold plating. 
     Next, a soldermask is described. First, a soldermask film is formed on the board surface, and then, a pattern is formed by photolithographic techniques. This is a soldermask. The soldermask cannot therefore form within the cavity  29 . Because, soldermask is exposed to light by techniques such as contact photolithography so the interior of the cavity  29  cannot be exposed to light. 
     The mounting pad  30 - 1 , the mounting pad  30 - 2 , the wire  26 - 1 , the wire  26 - 2 , the through hole  25 - 1 , and the through hole  25 - 2  are conductors exposed within the cavity  29 , and are all applied to the surface treatment. 
     The solder  27  connects the chip component  40 , the mounting pad  30 - 1 , and the mounting pad  30 - 2 . 
     In the first exemplary embodiment of the present invention, the mounting pad  30 - 1  (mounting pad  30 - 2 ) where the chip component  40  is mounted within the cavity  29 , is not directly connected to the through hole land  25 - 3  (through hole land  25 - 4 ). The size of the mounting pad  30 - 1  (mounting pad  30 - 2 ) can therefore be enlarged since these two components are not directly connected, rendering the effect of improving the parts connection reliability. 
     This effect is obtained due to the existence of the wire  26 - 1  (wire  26 - 2 ) connecting the mounting pad  30 - 1  (mounting pad  30 - 2 ) and the through hole land  25 - 3  (through hole land  25 - 4 ). 
     The second exemplary embodiment of the present invention is described next in detail while referring to the drawings. The second exemplary embodiment of the present invention is a method for manufacturing the wiring board  20  of the first exemplary embodiment of the present invention.  FIG. 2  is a drawing for describing the solder wicking on the wiring board  20 . In  FIG. 2 , the solder  27  supplied to the mounting pad  30 - 1  and mounting pad  30 - 2  wets the wire  26 - 1 , the wire  26 - 2 , the through hole  25 - 1 , and the through hole  25 - 2  during reflow, and possibly cause solder wicking. The solder wicking occurs because the surface treatment applied to the wire  26 - 1  the wire  26 - 2 , the through hole  25 - 1 , and the through hole  25 - 2  which ought not to be wet. 
     The second exemplary embodiment of the present invention is described in detail while referring to the drawings.  FIG. 3  is a drawing showing the cavity  35 - 1  and the cavity  35 - 2  of the wiring board  20  of the second exemplary embodiment of the present invention.  FIG. 4  is a flowchart for showing the method for forming the cavity  35 - 1 ,  35 - 2  of the second exemplary embodiment of the present invention. 
     A small cavity  35 - 1  is formed so that the mounting pad  30 - 1 , the mounting pad  30 - 2  are exposed, and the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are not exposed ( FIG. 3A , and step S 1  in  FIG. 4 ). A non-electrolytic nickel plating  33  and a non-electrolytic gold plating  34  are formed on the surface of the mounting pad  30 - 1  and the mounting pad  30 - 2  (step S 2 ). Mounting a component in the cavity  35 - 1  is difficult at this time. 
     The cavity  35 - 2  whose size is the outer dimension of the mounting component (the chip component  40 )+α[mm] (for example α=3, but is not limited to 3) is formed so that the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are exposed ( FIG. 3B , step S 3  of  FIG. 4 ). 
     The non-electrolytic nickel plating  33  is applied to the surface of the newly exposed wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  (step S 4 ). There is no need to apply non-electrolytic nickel plating to the surfaces of the mounting pad  30 - 1  and mounting pad  30 - 2  where the non-electrolytic nickel plating  33  and non-electrolytic gold plating  34  were already applied. 
     The non-electrolytic gold plating  34  need not be applied to the surfaces of the newly exposed wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  at this point. 
     The second exemplary embodiment of the present invention renders the effect of preventing solder wicking. Solder wicking is prevented because the cavity  35 - 1  formed at first, and then the cavity  35 - 2  formed so that that surface treatment is selective and only the conductive piece (pads) are soldered. 
     A third exemplary embodiment of the present invention is described in detail next while referring to the drawings.  FIGS. 5A and 5B  is a drawing for describing the third exemplary embodiment of the present invention.  FIG. 6  is a flow chart for describing the manufacturing method for the third exemplary embodiment of the present invention. 
     As shown in  FIG. 5A ,  5 B and  FIG. 6 , the cavity  29  whose size is the outer dimension of the mounting component (chip component  40 )+α[mm] is formed so that the mounting pad  30 - 1 , the mounting pad  30 - 2 , the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are exposed (step S 5  in  FIG. 6 ). The non-electrolytic nickel plating  33  and the non-electrolytic gold plating  34  are applied to the mounting pad  30 - 1 , the mounting pad  30 - 2 , the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  ( FIG. 5A , step S 6  in  FIG. 6 ). The non-electrolytic gold plating  34  on the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  is mechanically polished and cut to expose the non-electrolytic nickel plating  33  ( FIG. 5B , step S 7  in  FIG. 6 ). 
     The third exemplary embodiment of the present invention renders the effect of preventing solder wicking during mounting of the chip component  40 . The solder wicking is prevented because the non-electrolytic gold plating  34  is wetted by the solder  27  but the nickel surface of the non-electrolytic nickel plating  33  is oxidized and so is not easily wetted by the solder  27 . 
     A fourth exemplary embodiment of the present invention is described in detail while referring to the drawings.  FIG. 7  is a drawing showing the wiring board  20  of the fourth exemplary embodiment of the present invention. The fourth exemplary embodiment of the present invention is a wiring board and a method for manufacturing that board. 
     As shown in  FIG. 7 , the cavity  29  is formed in a tapered shape so that the mounting pad  30 - 1  and the mounting pad  30 - 2  are exposed but the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are not exposed. 
     The non-electrolytic nickel plating  33  and the non-electrolytic gold plating  34  are formed on the surface of the mounting pad  30 - 1  and the mounting pad  30 - 2 . 
     The fourth exemplary embodiment of the present invention renders the effect of resolving irregularities in the mounting position and irregularities in the outer dimension of the chip component  40 . These irregularities can be resolved on account of the tapered shape of the cavity  29 . 
     A fifth exemplary embodiment of the present invention is described in detail while referring to the drawings.  FIG. 8  is a drawing showing the wiring board  20  of the fifth exemplary embodiment of the present invention. The fifth exemplary embodiment of the present invention is a wiring board and a method for manufacturing that board. 
     As shown in  FIG. 8 , the cavity  29  is formed in a step shape so that the mounting pad  30 - 1  and the mounting pad  30 - 2  are exposed but the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are not exposed. 
     The non-electrolytic nickel plating  33  and the non-electrolytic gold plating  34  are formed on the surface of the mounting pad  30 - 1  and the mounting pad  30 - 2 . 
     The fifth exemplary embodiment of the present invention renders the effect of resolving irregularities in the mounting position and irregularities in the outer dimension of the chip component  40  and the effect is greater than that of the fourth exemplary embodiment. These irregularities can be resolved on account of the step shape of the cavity  29 . 
     A sixth exemplary embodiment of the present invention is described in detail while referring to the drawings.  FIG. 9  is a drawing showing the wiring board  20  of the sixth exemplary embodiment of the present invention. The sixth exemplary embodiment of the present invention is a wiring board and a method for manufacturing that board. 
     As shown in  FIG. 9 , a projection is formed on the surface of the cavity  29  so that the mounting pad  30 - 1  and the mounting pad  30 - 2  are exposed but the wire  26 - 1 , the wire  26 - 2 , the through hole land  25 - 3 , and the through hole land  25 - 4  are not exposed. 
     The non-electrolytic nickel plating  33  and the non-electrolytic gold plating  34  are formed on the surface of the mounting pad  30 - 1  and the mounting pad  30 - 2 . The projection can also be applied to the first through the fifth exemplary embodiments. The sixth exemplary embodiment of the present invention renders the effect of dissipating heat. The reason for the heat dissipating effect is the projection. 
     Numerical controlled machine tools as described in the Laid-Open Hei No. 10-22643 can be utilized for the actual forming of the cavity  29 ,  35 - 1  and  35 - 2  in the first through the sixth exemplary embodiments. 
     This invention renders the effect of improving the reliability of connections. The connection reliability is improved because the existence of the wire connecting the through hole land to the mounting pads in the cavity on the wiring board. 
     A first wiring board of this invention includes separate mounting pads for mounting the components and the through hole lands of the through holes in the cavity, and also wiring connecting the through hole land and mounting pad. 
     A second wiring board of this invention according to the first wiring board includes a through hole land of the through hole for connecting to an inner layer ground plane and, a through hole land for a through hole connecting to an inner layer power supply plane. 
     A third wiring board of this invention according to the first or the second wiring board includes mounting pads subjected to non-electrolytic nickel plating and non-electrolytic gold plating. 
     A fourth wiring board of this invention according to any of the first through third wiring boards includes a through hole land subjected to non-electrolytic nickel plating and non-electrolytic gold plating. 
     A fifth wiring board of this invention according to any of the first through fourth wiring boards containing components connected by solder and mounting pads. 
     A sixth wiring board of this invention according to any of the first, second, third or fifth wiring boards where the mounting pads are exposed, and containing tapered cavities where the wiring and through hole lands are not exposed. 
     A seventh wiring board of this invention according to any of the first, second, third or fifth wiring boards where the mounting pads are exposed, and containing step-shaped cavities where the wiring and through hole lands are not exposed. 
     An eighth wiring board of this invention according to any of the first, second, third, sixth or seventh wiring boards where the cavities contains protrusions. 
     A first wiring board manufacturing method of this invention contains separate mounting pads for mounting the components and the through hole lands of the through holes in the cavity, and wiring for connecting the through hole lands to the mounting pads; and includes: a first process for forming cavities where the mounting pads are exposed, and the wiring and through hole lands are not exposed and; a second process for performing non-electrolytic gold plating and; a third process for forming cavities where the wiring and through hole lands are exposed. 
     A second wiring board manufacturing method of this invention according to the first wiring board manufacturing method, includes a fourth process for performing non-electrolytic nickel plating on the wiring and the through hole lands. 
     A third wiring board manufacturing method of this invention contains separate mounting pads for mounting the components and the through hole lands of the through holes in the cavity, and wiring for connecting the through hole lands to the mounting pads; and including: a first process for forming cavities where the mounting pads, the wiring, and through hole lands are exposed and; a second process for forming a non-electrolytic nickel plating  33  and a non-electrolytic gold plating on the mounting pads, the wiring, and the through hole lands; and a third process for cutting the non-electrolytic gold plating on the through hole lands and the wiring, and exposing the non-electrolytic nickel plating. 
     A fourth wiring board manufacturing method of this invention contains separate mounting pads for mounting the components and the through hole lands of the through holes in the cavity, and wiring for connecting the through hole lands to the mounting pads; and including: a process for forming a tapered cavity where the mounting pads are exposed but the wiring and through hole lands are not exposed. 
     A fifth wiring board manufacturing method of this invention contains separate mounting pads for mounting the components and the through hole lands of the through holes in the cavity, and wiring for connecting the through hole lands to the mounting pads; and a process for forming a stepped cavity where the mounting pads are exposed but the wiring and through hole lands are not exposed. 
     While this invention has been described in conjunction with the preferred embodiments described above, the invention can also be implemented in various forms and adaptations by those skilled in the art.