Abstract:
A laminated inductor, as well as a method of manufacturing such a laminated inductor, are provided. The laminated inductor includes: a laminate; a pair of external electrodes arranged on the outer surfaces of the laminate respectively; and a coil, arranged within the laminate and formed by electrically connecting a plurality of strip-like conductor patterns. The conductor patterns have: a pair of broad faces, intersecting the lamination direction and mutually opposing; and peripheral side faces adjacent to the pair of broad faces and extending in the lamination direction. The peripheral side faces are concavo-convex faces, in which concave portions and convex portions are arranged in alternation in the lamination direction. The laminate enters into the concave portions of the peripheral side faces.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   This invention relates to a laminated inductor, and to a method of manufacture of a laminated inductor. 
   2. Related Background Art 
   In the prior art, methods are known for the manufacture of couplers and other electronic components in which laser light is used to form grooves in a green sheet, and the grooves are filled with a conductive paste, for the purpose of increasing the thickness of the conduction pattern and reducing electrical resistance (see for example Patent Literature 1). An electronic component manufactured by such a method of electronic component manufacture comprises a laminate, in which a plurality of insulator layers are laminated, and a strip-like conductor pattern positioned within the laminate. The conductor pattern has a pair of broad faces, and peripheral side faces which connect the pair of broad faces over the entire perimeter of the pair of broad faces. 
   Patent Literature 1: Japanese Unexamined Patent Publication No. 2006-041017 
   SUMMARY OF THE INVENTION 
   In recent years there have been demands for laminated inductors for use as power supply choke coils in for example portable telephones which have satisfactory DC superposition characteristics (small DC resistance values) and small decreases in the inductance value even when large DC currents (for example, approximately 1 A to 5 A) are passed. To this end, by adopting the above-described method of electronic component manufacture of the prior art, a laminated inductor having thick conductor patterns may be obtainable. 
   However, when adopting a method of electronic component manufacture of the prior art, in general the conductive paste and the green sheet are prepared such that the shrinkage rate of the conductive paste during burning is greater than the shrinkage rate of the green sheet during burning; and so to the extent that the conductor pattern thickness is increased, a gap tends to occur between the peripheral side faces of the conductor pattern in the manufactured laminated inductor and the portions of the laminate in contact with the side faces. For this reason, the occurrence of gaps is accompanied by advancing separation between the peripheral side faces of the conductor pattern and the portions of the laminate in contact with the peripheral side faces, and there has been the problem that cracking occurs in portions of the laminate positioned between adjacent conductor patterns in the lamination direction. When such cracking occurs, due to a migration phenomenon in which the conductor pattern moves within the crack, there is the possibility of short-circuits between adjacent conductor patterns. 
   Hence, this invention has as an object the provision of a laminated inductor, in which cracks are highly unlikely to occur in portions positioned between adjacent conductor patterns in the lamination direction within the laminate, even when the conductor pattern thickness is large, as well as a method of manufacture of such a laminated inductor. 
   A laminated inductor of this invention has a laminate formed by laminating a plurality of insulator layers; first and second external electrodes positioned on outer surfaces of the laminate respectively; a coil, formed by electrically connecting a plurality of strip-like conductor patterns, and arranged within the laminate; a first leading conductor, electrically connected to one end of the coil, and electrically connected to the first external electrode; and a second leading conductor, electrically connected to the other end of the coil, and electrically connected to the second external electrode; the conductor pattern has first and second broad faces, mutually opposing in the lamination direction of the laminate, and peripheral side faces connecting the first and second broad faces over the entire perimeter of the first and second broad faces, and is set to have a thickness of 20 μm or greater; the peripheral side faces have concave portions extending along the peripheral direction and convex portions extending along the peripheral direction, which are arranged in alternation along the lamination direction to form concavo-convex faces; and by causing a portion of the laminate to enter into the concave portions of the peripheral side faces, the conductor pattern, seen from the lamination direction, has overlapping portions, in which portions, of the laminate, which enter into the concave portions in the peripheral side faces overlap the conductor pattern, and non-overlapping portions which are portions other than the overlapping portions. 
   In a laminated inductor of this invention, peripheral side faces of the conductor pattern form concavo-convex faces, with alternation of concave portions and convex portions of the peripheral side face in the lamination direction, and with a portion of the laminate entering into the concave portions of the peripheral side faces. As a result, due to a so-called anchor effect, there is extremely little tendency for separation of the portions of the laminate in contact with the peripheral side faces of the conductor pattern from the concavo-convex shape peripheral side faces. As a result, even when the conductor pattern is thick (20 μm or greater), there is extremely little tendency for cracking to occur in portions of the laminate positioned between adjacent conductor patterns in the lamination direction. Hence, concerns about short-circuits between adjacent conductor patterns due to the migration phenomenon are greatly reduced. 
   It is preferable that the width of the conductor pattern be set to greater than 60 μm, and that the width of the overlapping portions be set to 20 μm or greater, and moreover be smaller than the width of the non-overlapping portions. If the width of overlapping portions is less than 20 μm, there is a tendency for the anchor effect (the effect of impeding separation of the concavo-convex shape peripheral side faces from the laminate) occurring due to the concavo-convex shape peripheral side faces of the conductor pattern to be inadequate. If the width of the overlapping portions is equal to or greater than the width of the non-overlapping portions, the relative cross-sectional area of the conductor pattern is small, and there is a tendency for the DC resistance value of the laminated inductor to be high; such a laminated inductor is not well-suited to large-current applications. 
   It is preferable that the tips of the convex portions in the peripheral side faces have a tapered shape. By this means, there is extremely little tendency for the portions of the laminate in contact with the peripheral side faces of the conduction pattern to separate from the concavo-convex shape peripheral side faces. 
   It is preferable that the laminate have first and second main faces, which intersect the lamination direction and are mutually opposed, and that the conductor pattern is arranged within the laminate such that the first broad faces are closer to the first main face and the second broad faces are closer to the second main face, that the tips of convex portions, when seen from the lamination direction, substantially coincide with edges of the first and second broad faces, so that as a result bottoms of the concave portions overlap the first and second broad faces when seen from the lamination direction, that regions on the first broad faces in the overlapping portions are in contact with the laminate, and that a gap is formed between a portion of the regions of the first broad faces in the non-overlapping portions and the laminate. By this means, because the relative permittivity of air is lower than the relative permittivity of the laminate, the distributed capacitance is small. As a result, losses at high frequencies can be made small. 
   It is still more preferable that the conductor pattern have end portions connected to through-hole conductors extending in the lamination direction, that the conductor pattern and through-hole conductors be connected via connection conductors provided only at the end portions of the conductor pattern, and that the connection conductors be arranged so as to be larger than the through-hold conductors when seen from the lamination direction and so as to be within regions in the non-overlapping portions of the first broad faces. By this means, the conductor pattern and through-hole conductors can be reliably connected by the connection conductors, so that the reliability of connection can be greatly enhanced. 
   On the other hand, a method of manufacturing a laminated inductor of this invention is characterized in comprising a green sheet preparation process of preparing a green sheet; a first conductive film formation process of forming a strip-like first conductive film by applying a conductive paste onto the green sheet in a prescribed pattern and performing drying; a first ceramic film formation process of applying a ceramic slurry so as to cover the edge portions of the first conductive film and expose an upper face of the first conductive film other than the edge portions, and performing drying to form a first ceramic film; a second conductive film formation process of applying a conductive paste on the exposed face of the first conductive film and on the first ceramic film in the prescribed pattern and performing drying, in order to form a strip-like second conductive film, which overlaps with the first conductive film when seen from the lamination direction; and, a second ceramic film formation process of applying a ceramic slurry so as to cover the edge portions of the second conductive film and expose an upper face of the second conductive film other than the edge portions, and performing drying, in order to form a second ceramic film. 
   In a method of manufacturing a laminated inductor of this invention, a first ceramic film is formed so as to cover the edge portions of the first conductive film as well as exposing the upper face of the first conductive film other than the edge portions, a second conductive film is formed on the exposed face of the first conductive film and on the first ceramic film with the same pattern as the first conductive film, and a second ceramic film is formed so as to cover the edge portions of the second conductive film while exposing the upper face of the second conductive film other than the edge portions. Hence, by means of this method of manufacture of laminated inductors of the invention, a laminated inductor can be manufactured in which the peripheral side faces of the conductor pattern form the concavo-convex faces in which the concave portions and the convex portions alternate in the lamination direction, and moreover the laminate enters into the depressed portions of the peripheral side faces. As a result, because of the so-called anchor effect, there is extremely little tendency for separation of the laminate from the concavo-convex shape peripheral side faces, and there is extremely little tendency for cracks to occur in the portions of the laminate positioned between adjacent conductor patterns in the lamination direction. Hence, concerns about short-circuits between adjacent conductor patterns due to the migration phenomenon are greatly reduced. 
   It is preferable that in the first ceramic film formation process, the first ceramic film be formed such that the height of the first ceramic film from the green sheet is higher than the height of the first conductive film from the green sheet, and that in the second ceramic film formation process, the second ceramic film be formed such that the height of the second ceramic film from the green sheet is higher than the height of the second conductive film from the green sheet. By this means, when a plurality of green sheets are laminated, the green sheet laminate as a whole can be uniformly pressure-bonded. As a result, the occurrence of interlayer separation within the manufactured laminated inductor can be adequately suppressed. 
   It is still more preferable that the through-hole formation process of forming through-holes penetrating the green sheet in the thickness direction be further comprised after the green sheet preparation process and before the first conductive film formation process, and that connection conductive film formation processes be further comprised in which, in the first conductive film formation process, by filling the through-holes with conductive paste as well as applying conductive paste onto the green sheet in a prescribed pattern and performing drying, the strip-like first conductive film is formed, and after the second ceramic film formation process, by applying conductive paste only to an end portion of the second conductive film which are the exposed face of the second conductive film and then performing drying, the connection conductive film is formed the height of which from the green sheet is greater than the height of the ceramic film from the green sheet. In this way, when laminating a plurality of green sheets, the connection conductive film formed on the exposed face of the second conductive film on one green sheet is crushed by the other green sheet adjacent to this green sheet, and by means of this connection conductive film, the second conductive film on one green sheet is reliably connected to the portion of the first conductive film on the other green sheet which fills through-holes formed in the other green sheet, to greatly improve the reliability of connection. Hence, both suppression of interlayer separation, and reduction of connection faults can be achieved. 
   It is still more preferable that the shrinkage rate during burning of the connection conductive film be smaller than the shrinkage rate during burning of the conductive film. By this means, there is little tendency for shrinkage of the connection conductive film during burning, so that even after burning, the connection between the second conductive film on one green sheet and the portion of the first conductive film on other green sheet which fills through-holes formed in the other green sheet can be reliably maintained. As a result, connection faults can be further reduced. 
   Further, a method of manufacturing a laminated inductors of this invention comprises a green sheet preparation process of preparing a green sheet; a through-hole formation process of forming through-holes in the green sheet, which penetrates in the thickness direction; a first conductive film formation method of forming a strip-like first conductive film by filling the through-holes with conductive paste and applying conductive paste onto the green sheet in a prescribed pattern and performing drying; a first ceramic film formation method of applying a ceramic slurry so as to cover edge portions of the first conductive film and expose the upper face of the first conductive film other than the edge portions, and performing drying, in order to form a first ceramic film having the height, from the green sheet, greater than the height of the first conductive film from the green sheet; an n th  conductive film formation process of forming a strip-like n th  (where n th  is an integer equal to or greater than 2) conductive film; an n th  ceramic film formation process of forming an n th  ceramic film; and, a connection conductive film formation process; and wherein, in the n th  conductive film formation process, by applying conductive paste in the prescribed pattern onto the exposed face of the m th  (where m is the integer satisfying m=n−1) conductive film and onto the m th  ceramic film and by performing drying, the n th  conductive film is formed so as to overlap the m th  conductive film when seen from the lamination direction and to have the height, from the green sheet, greater than the height of the m th  ceramic film from the green sheet; in the n th  ceramic film formation process, by applying ceramic slurry so as to cover edge portions of the n th  conductive film and expose the upper face of the n th  conductive film other than the edge portions and by performing drying, the n th  ceramic film is formed to have the height, from the green sheet, greater than the height of the n th  conductive film from the green sheet; and, in the connection conductive film formation process, by applying conductive paste only onto end portions of the n th  conductive film which is the exposed face and by performing drying, the connection conductive film is formed to have the height, from the green sheet, greater than the height of the n th  ceramic film from the green sheet. 
   In a method of manufacturing a laminated inductor of this invention, the m th  ceramic film is formed so as to cover the edge portions of the m th  conductive film and expose the upper face of the m th  conductive film other than the edge portions, the n th  conductive film is formed on the exposed face of the m th  conductive film and the m th  ceramic film with the same pattern as the m th  conductive film, and the n th  ceramic film is formed so as to cover the edge portions of the n th  conductive film and expose the upper face of the n th  conductive film other than the edge portions. Hence, by means of a method of manufacture of laminated inductors of this invention, the peripheral side faces of the conductor pattern are formed as concavo-convex faces in which concave portions and convex portions are alternated in the lamination direction, and a laminated inductor can be manufactured with the laminate entering into the concave portions of the peripheral side faces. As a result, due to the so-called anchor effect, there is extremely little tendency for separation of the laminate from the depression/protrusion shape peripheral side faces, and so there is very little tendency for cracking to occur in the portions of the laminate positioned between adjacent conductor patterns in the lamination direction. Hence, concerns about short-circuits between adjacent conductor patterns due to the migration phenomenon are greatly reduced. 
   Further, in a method of manufacture of laminated inductors of this invention, the n th  ceramic film is formed such that the edge portions of the n th  conductive film are covered and the upper face of the conductive film other than the edge portions is exposed, and such that the height of the n th  ceramic film from the green sheet is greater than the height of the n th  conductive film from the green sheet. Hence, compared with manufacturing methods of the prior art in which an auxiliary magnetic material layer was formed so as to surround the perimeter of the conductor pattern, when a plurality of green sheets are laminated, the area of contact between the n th  ceramic film formed on one green sheet and other green sheet adjacent to the one ceramic film increases, and by means of the edge portions of the n th  conductive film, together with the stronger pressing of the n th  ceramic film formed on the one green sheet with the other green sheet adjacent to the one green sheet, there is a reduced tendency for separation to occur in the manufactured laminated inductor. Moreover, in a method of manufacture of laminated inductors of this invention, the connection conductive film is formed on the exposed face of the n th  conductive film with a height from the green sheet greater than the height of the n th  ceramic film from the green sheet. Hence, when laminating a plurality of green sheets, the connection conductive film formed on the exposed face of the n th  conductive film on one green sheet is crushed by the other green sheet adjacent to this green sheet, and by means of this connection conductive film, the n th  conductive film on one green sheet is reliably connected to the portion of the first conductive film on the other green sheet which fills through-holes formed in the other green sheet, to greatly improve the reliability of connection. Hence, both suppression of interlayer separation, and reduction of connection faults can be achieved. 
   It is preferable that the shrinkage rate during burning of the connection conductive film be smaller than the shrinkage rate during burning of the first to n th  conductive film. As a result, there is little tendency for the connection conductive film to shrink during burning, so that even after burning, the connections between the n th  conductive film on one green sheet and the portions of the first conductive film on other green sheet which fill through-holes in the other green sheet can be reliably maintained. As a result, connection faults can be further reduced. 
   By means of this invention, a laminated inductor in which there is extremely little tendency for cracking in portions of the laminate positioned between adjacent conductor patterns in the lamination direction even when conductor patterns are thick, as well as a method of manufacture of such laminated inductors, can be provided. 
   The present invention will be more fully understood from the detailed description given herein below and the accompanying drawings, which are given by way of illustration only, and thus are not to be considered as limiting the present invention. 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
       FIG. 1  is a perspective view of the laminated inductor of an embodiment; 
       FIG. 2  is an exploded perspective view used to explain the configuration of a laminate comprised by the laminated inductor of this embodiment; 
       FIG. 3  is an exploded perspective view showing in enlargement a portion of  FIG. 2 ; 
       FIG. 4  is a cross-sectional view showing a state in which the laminate is sectioned along line IV-IV in  FIG. 2 ; 
       FIG. 5  is a cross-sectional view showing in enlargement a portion of  FIG. 4 ; 
       FIG. 6  shows a process in the manufacture of the laminated inductor of this embodiment; 
       FIG. 7  shows a process following that of  FIG. 6 ; 
       FIG. 8  shows a process following that of  FIG. 7 ; 
       FIG. 9  shows a process following that of  FIG. 8 ; and, 
     (a) of  FIG. 10  is a figure which explains the amount of protrusion X of the conductive film, and (b) of  FIG. 10  shows the relationship between the amount of protrusion X of the conductive film and the rate of line breakage and the rate of occurrence of cracking. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Preferred embodiments of the invention are explained referring to the drawings. In the explanations, the same symbols are used for the same elements or for elements having the same functions, and redundant explanations are omitted. 
   (Configuration of Laminated Inductor) 
   First, the configuration of the laminated inductor  10  of an embodiment is explained, referring to  FIG. 1  to  FIG. 5 . As shown in  FIG. 1  and  FIG. 2 , the laminated inductor  10  comprises a laminate  12  with substantially a rectangular parallelepiped shape; a pair of external electrodes  14  and  16 , formed on the two peripheral side faces respectively in the length direction of the laminate  12 ; and a coil L, formed by electrically connecting each of conductor patterns C 1  to C 12  within the laminate  12 . 
   The laminate  12  has a pair of main faces  12   a ,  12   b , which are opposed so as to be substantially parallel. One among the main faces  12   a ,  12   b  is a face which, when the laminated inductor  10  is mounted on an external substrate (not shown), opposes the external substrate. 
   As shown in  FIG. 2 , the laminate  12  is formed by laminating, in order, magnetic layers A 1  to A 4 , a nonmagnetic layer B 1 , magnetic layers A 5  to A 7 , a nonmagnetic layer B 2 , and magnetic layers A 8  to A 12 . That is, the upper face of the magnetic layer A 1  forms the main face  12   a  of the laminate  12 , and the lower face of the magnetic layer A 12  forms the main face  12   b  of the laminate  12  (see  FIG. 2 ); in this embodiment, the direction of opposition of the main faces  12   a  and  12   b  (hereafter called the “opposition direction”) coincides with the lamination direction (hereafter the “lamination direction”) of the laminate  12  (magnetic layers A 1  to A 12  and nonmagnetic layers B 1  and B 2 ). 
   The magnetic layers A 1  to A 12 , the nonmagnetic layers B 1  and B 2 , and magnetic films F 1  to F 10  described below function as insulators having electrical insulation properties. The magnetic layers A 1  to A 12  and the magnetic films F 1  to F 10  can be formed using, for example, Ni—Cu—Zn based ferrites, Cu—Zn based ferrites, or Ni—Cu—Zn—Mg based ferrites, or similar. The nonmagnetic layers B 1  and B 2  can for example be formed using Cu—Zn based nonmagnetic ferrites or other nonmagnetic ferrites. In an actual laminated inductor  10 , the magnetic layers A 1  to A 12 , the nonmagnetic layers B 1  and B 2 , and the magnetic films F 1  to F 10  are integrated to such an extent that the boundaries therebetween cannot be perceived. 
   The conductor pattern C 1  and a leading conductor D 1  are formed on the surface of the magnetic layer A 2 . The conductor pattern C 1  is arranged so as to be at the position of one end of the coil L. One end of the conductor pattern C 1  is integrally formed with the leading conductor D 1 . The leading conductor D 1  leads to the side on which the external electrode  12  of the magnetic layer A 2  is formed, and the end portion thereof is exposed on an end face of the magnetic layer A 2 . Hence, the conductor pattern C 1  is electrically connected to the external electrode  12  via the leading conductor D 1 . The other end of the conductor pattern C 1  is electrically connected to a cylindrical through-hole conductor E 1  which is formed penetrating the magnetic layer A 2  in the thickness direction (that is, extends along the lamination direction). Hence, in the laminated state, the conductor pattern C 1  is electrically connected to the corresponding conductor pattern C 2  via the through-hole conductor E 1  and a connection conductor G 1  (which is described in detail below). 
   The conductor pattern C 2  and the magnetic film F 1  are formed on the surface of the magnetic layer A 3 . The conductor pattern C 2  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 3 . The connection conductor G 1  is provided on the surface of one end of the conductor pattern C 2 ; this connection conductor G 1  is connected to the through-hole conductor E 1  in the laminated state. That is, the conductor pattern C 2  has an end portion which is connected with the through-hole conductor E 1  via the connection conductor G 1 . The other end of the conductor pattern C 2  is electrically connected to a cylindrical through-hole conductor E 2 , which is formed penetrating the magnetic layer A 3  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 2  is electrically connected to the corresponding conductor pattern C 3  via the through-hole conductor E 2  and a connection conductor G 2  (which is described in detail below). 
   The conductor pattern C 3  and the magnetic film F 2  are formed on the surface of the magnetic layer A 4 . The conductor pattern C 3  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 4 . The connection conductor G 2  is provided on the surface of one end of the conductor pattern C 3 ; this connection conductor G 2  is connected to the through-hole conductor E 2  in the laminated state. That is, the conductor pattern C 3  has an end portion which is connected with the through-hole conductor E 2  via the connection conductor G 2 . The other end of the conductor pattern C 3  is electrically connected to a cylindrical through-hole conductor E 3 , which is formed penetrating the magnetic layer A 4  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 3  is electrically connected to the corresponding conductor pattern C 4  via the through-hole conductor E 3  and a connection conductor G 3  (which is described in detail below). 
   The conductor pattern C 4  and the magnetic film F 3  are formed on the surface of the nonmagnetic layer B 1 . The conductor pattern C 4  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the nonmagnetic layer B 1 . The connection conductor G 3  is provided on the surface of one end of the conductor pattern C 4 ; this connection conductor G 3  is connected to the through-hole conductor E 3  in the laminated state. That is, the conductor pattern C 4  has an end portion which is connected with the through-hole conductor E 3  via the connection conductor G 3 . The other end of the conductor pattern C 4  is electrically connected to a cylindrical through-hole conductor E 4 , which is formed penetrating the nonmagnetic layer B 1  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 4  is electrically connected to the corresponding conductor pattern C 5  via the through-hole conductor E 4  and a connection conductor G 4  (which is described in detail below). 
   The conductor pattern C 5  and the magnetic film F 4  are formed on the surface of the magnetic layer A 5 . The conductor pattern C 5  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 5 . The connection conductor G 4  is provided on the surface of one end of the conductor pattern C 5 ; this connection conductor G 4  is connected to the through-hole conductor E 4  in the laminated state. That is, the conductor pattern C 5  has an end portion which is connected with the through-hole conductor E 4  via the connection conductor G 4 . The other end of the conductor pattern C 5  is electrically connected to a cylindrical through-hole conductor E 5 , which is formed penetrating the magnetic layer A 5  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 5  is electrically connected to the corresponding conductor pattern C 6  via the through-hole conductor E 5  and a connection conductor G 5  (which is described in detail below). 
   The conductor pattern C 6  and the magnetic film F 5  are formed on the surface of the magnetic layer A 6 . The conductor pattern C 6  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 6 . The connection conductor G 5  is provided on the surface of one end of the conductor pattern C 6 ; this connection conductor G 5  is connected to the through-hole conductor E 5  in the laminated state. That is, the conductor pattern C 6  has an end portion which is connected with the through-hole conductor E 5  via the connection conductor G 5 . The other end of the conductor pattern C 6  is electrically connected to a cylindrical through-hole conductor E 6 , which is formed penetrating the magnetic layer A 6  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 6  is electrically connected to the corresponding conductor pattern C 7  via the through-hole conductor E 6  and a connection conductor G 6  (which is described in detail below). 
   The conductor pattern C 7  and the magnetic film F 6  are formed on the surface of the magnetic layer A 7 . The conductor pattern C 7  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 7 . The connection conductor G 6  is provided on the surface of one end of the conductor pattern C 7 ; this connection conductor G 6  is connected to the through-hole conductor E 6  in the laminated state. That is, the conductor pattern C 7  has an end portion which is connected with the through-hole conductor E 6  via the connection conductor G 6 . The other end of the conductor pattern C 7  is electrically connected to a cylindrical through-hole conductor E 7 , which is formed penetrating the magnetic layer A 7  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 7  is electrically connected to the corresponding conductor pattern C 8  via the through-hole conductor E 7  and a connection conductor G 7  (which is described in detail below). 
   The conductor pattern C 8  and the magnetic film F 7  are formed on the surface of the nonmagnetic layer B 2 . The conductor pattern C 8  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the nonmagnetic layer B 2 . The connection conductor G 7  is provided on the surface of one end of the conductor pattern C 8 ; this connection conductor G 7  is connected to the through-hole conductor E 7  in the laminated state. That is, the conductor pattern C 8  has an end portion which is connected with the through-hole conductor E 7  via the connection conductor G 7 . The other end of the conductor pattern C 8  is electrically connected to a cylindrical through-hole conductor E 8 , which is formed penetrating the nonmagnetic layer B 2  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 8  is electrically connected to the corresponding conductor pattern C 9  via the through-hole conductor E 8  and a connection conductor G 8  (which is described in detail below). 
   The conductor pattern C 9  and the magnetic film F 8  are formed on the surface of the magnetic layer A 8 . The conductor pattern C 9  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 8 . The connection conductor G 8  is provided on the surface of one end of the conductor pattern C 9 ; this connection conductor G 8  is connected to the through-hole conductor E 8  in the laminated state. That is, the conductor pattern C 9  has an end portion which is connected with the through-hole conductor E 8  via the connection conductor G 8 . The other end of the conductor pattern C 9  is electrically connected to a cylindrical through-hole conductor E 9 , which is formed penetrating the magnetic layer A 8  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 9  is electrically connected to the corresponding conductor pattern C 10  via the through-hole conductor E 9  and a connection conductor G 9  (which is described in detail below). 
   The conductor pattern C 10  and the magnetic film F 9  are formed on the surface of the magnetic layer A 9 . The conductor pattern C 10  has a strip-like shape, and is equivalent to substantially one turn of the coil L, winding in a spiral shape over the magnetic layer A 9 . The connection conductor G 9  is provided on the surface of one end of the conductor pattern C 10 ; this connection conductor G 9  is connected to the through-hole conductor E 9  in the laminated state. That is, the conductor pattern C 10  has an end portion which is connected with the through-hole conductor E 9  via the connection conductor G 9 . The other end of the conductor pattern C 10  is electrically connected to a cylindrical through-hole conductor E 10 , which is formed penetrating the magnetic layer A 9  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 10  is electrically connected to the corresponding conductor pattern C 11  via the through-hole conductor E 10  and a connection conductor G 10  (which is described in detail below). 
   The conductor pattern C 11  and the magnetic film F 10  are formed on the surface of the magnetic layer A 10 . The conductor pattern C 11  has a strip-like shape, and is equivalent to substantially ⅜ turn of the coil L, forming an L shape over the magnetic layer A 10 . The connection conductor G 10  is provided on the surface of one end of the conductor pattern C 11 ; this connection conductor G 10  is connected to the through-hole conductor E 10  in the laminated state. That is, the conductor pattern C 11  has an end portion which is connected with the through-hole conductor E 10  via the connection conductor G 10 . The other end of the conductor pattern C 11  is electrically connected to a cylindrical through-hole conductor E 11 , which is formed penetrating the magnetic layer A 10  in the thickness direction (that is, extending along the lamination direction). Hence, in the laminated state, the conductor pattern C 11  is electrically connected to the corresponding conductor pattern C 12  via the through-hole conductor E 11 . 
   The conductor pattern C 12  and a leading conductor D 2  are formed on the surface of the magnetic layer A 11 . One end of the conductor pattern C 12  comprises an area which is electrically connected to the through-hole electrode E 11  in the laminated state. The other end of the conductor pattern C 12  is integrally formed with the leading conductor D 2 . The leading conductor D 2  leads to the side on which the external electrode  14  of the magnetic layer A 11  is formed, and the end portion thereof is exposed on an end face of the magnetic layer A 11 . Hence, the conductor pattern C 12  is electrically connected to the external electrode  14  via the leading conductor D 2 . 
   Here, the configuration of the conductor patterns C 2  to C 11  is explained in greater detail, referring to  FIG. 3  to  FIG. 5 . In  FIG. 3  to  FIG. 5 , only portions of the conductor patterns C 2  to C 11  are shown, but the following explanation of the configuration of the conductor patterns C 2  to C 11  is common to all the conductor patterns. 
   The thickness of the conductor patterns C 2  to C 11  is set to 20 μm or greater, and it is preferable that the thickness be set to approximately 40 μm to 80 μm. If the thickness of the conductor patterns C 2  to C 11  is less than 20 μm, the cross-sectional area of the conductor patterns C 2  to C 11  is relatively small, and there is a tendency for the DC resistance value of the laminated inductor  10  to be large, making such a laminated inductor  10  unsuitable for large-current applications. 
   The conductor patterns C 2  to C 11  each have a pair of broad faces S 1  and S 2 , in mutual opposition in the lamination direction, and peripheral side faces S 3  connecting the broad face S 1  and the broad face S 2  along the entire perimeter of the pair of broad faces S 1  and S 2 . The conductor patterns C 2  to C 11  are arranged within the laminate  12  such that the broad faces S 1  are closer to the main face  12   a  and the broad faces S 2  are closer to the main face  12   b  (see  FIG. 4  in particular). 
   The peripheral side faces S 3  of the conductor patterns C 2  to C 11  are concavo-convex faces in which concave portions  18   a  and convex portions  18   b  are arranged in alternation in the lamination direction, as shown in  FIG. 3  to  FIG. 5 . The concave portions  18   a  and convex portions  18   b  extend along the peripheral direction of the peripheral side faces S 3  over the entire perimeters of the peripheral side faces S 3 . As shown in  FIG. 4  and  FIG. 5 , portions of the laminate  12  (magnetic films F 1  to F 10 ) enter into the concave portions  18   a . Consequently, as shown in  FIG. 5 , when seen from the lamination direction the conductor patterns C 2  to C 11  have overlapping portions  20   a  in which portions of the laminate  12  (magnetic films F 1  to F 10 ) enter into concave portions  18   a , and in which the conductor patterns C 2  to C 11  are overlapped, and non-overlapping portions  20   b  other than the overlapping portions  20   a . On the other hand, the tips of the convex portions  18   b  have a tapered shape. The tips of the convex portions  18   b  substantially coincide with the edges of the broad faces S 1  and S 2  when seen from the lamination direction. Hence, the bottoms of the concave portions  18   a  overlap the broad faces S 1  and S 2  when seen from the lamination direction. 
   The width W 1  of the conductor patterns C 2  to C 11  (see  FIG. 5 ) is set to greater than 60 μm, and preferably is set to approximately 200 μm to 300 μm. The width W 2  of the overlapping portions  20   a  (see  FIG. 5 ) is set to 20 μm or greater, and so as to be smaller than the width W 3  of the non-overlapping portions  20   b  (see  FIG. 5 ). If the width W 2  of the overlapping portion  20   a  is smaller than 20 μm, the anchor effect occurring due to the depression/protrusion shape of the peripheral side faces S 3  (the effect by which there is little tendency for separation of the laminate  12  from the concavo-convex shape peripheral side faces S 3 ) tends to be inadequate. If the width W 2  of the overlapping portions  20   a  is equal to or greater than the width W 3  of the non-overlapping portions  20   b , the cross-sectional area of the conductor patterns C 2  to C 11  is relatively small, the DC resistance value of the laminated inductor  10  tends to be large, and such a laminated inductor  10  is not suitable for large-current applications. 
   As shown in  FIG. 5 , the areas S 1   a  in the overlapping portions  20   a  among the broad faces S 1  of the conductor patterns C 2  to C 11  are in contact with the laminate  12  (magnetic films F 1  to F 10 ). On the other hand, as shown in  FIG. 5 , the areas S 1   b  in the non-overlapping portions  20   b  among the broad faces S 1  of the conductor patterns C 2  to C 11  are not in contact with the laminate  12  (magnetic films F 1  to F 10 ). Moreover, the portions of the areas S 1   b  corresponding to the through-hole conductors E 1  to E 10  have a cylindrical shape or a truncated hemispherical shape, and moreover connection conductors G 1  to G 10  are positioned which, when seen from the lamination direction, are larger than the through-hole conductors E 1  to E 10 . That is, the connection conductors G 1  to G 10  are provided only at the end portions of the conductor patterns C 2  to C 11 . Between the portions of the areas S 1   b  excluding the portions in which the connection conductors G 1  to G 10  are positioned (that is, the areas indicated by diagonal lines in  FIG. 3 ) and the laminate  12 , gaps V are formed (see  FIG. 5 ). 
   The broad faces S 2  of the conductor patterns C 2  to C 11  are in contact with the laminate  12  either entirely or for the most part, as shown in  FIG. 3  to  FIG. 5 . 
   The above-described conductor patterns C 1  to C 12  and the leading conductors D 1  and D 2  can for example be formed using Ag or another metal material. The thicknesses of the above-described conductor patterns C 1  and C 12  and the leading conductors D 1  and D 2  can be set to approximately 10 μm to 25 μm, and the widths of the above-described conductor patterns C 1  and C 12  can be set to approximately 200 μm to 300 μm. 
   (Method of Manufacture of Laminated Inductor) 
   Next, a method of manufacture of laminated inductors  10  of this embodiment is explained, referring to  FIG. 6  to  FIG. 9 . In  FIG. 6  to  FIG. 9 , only a portion of magnetic green sheets GS 1  and of nonmagnetic green sheets GS 2  are shown; but the processes for formation of conductive films H 1  to H 4  and magnetic films I 1  to I 4  described below on the magnetic green sheet GS 1  or the nonmagnetic green sheet GS 2  are all common to all sheets. 
   First, a magnetic slurry, nonmagnetic slurry, conductive paste and connection conductive paste are prepared. Specifically, the magnetic slurry is obtained by for example kneading Ni—Cu—Zn based ferrite powder, Cu—Zn based ferrite powder, or Ni—Cu—Zn—Mg based ferrite powder, or another magnetic powder, with a binder and solvent. The nonmagnetic slurry is obtained by for example kneading Cu—Zn based nonmagnetic ferrite powder, or another nonmagnetic powder, with a binder and solvent. The conductive paste and connection conductive paste are prepared by for example mixing a conductive powder with a binder and organic solvent at a prescribed mixing ratio, and then kneading. As the conductive powder, normally Ag, an Ag alloy, Cu, a Cu alloy, or similar can be used; however, it is preferable that Ag, with its low resistivity, be used. In kneading, three rollers, a homogenizer, a sand mill, or similar can be used. In order to ensure that the shrinkage after burning of the connection conductor paste is smaller than conductive paste shrinkage after burning, for example the types and amounts of binders and solvents in the conductive paste and in the connection conductive paste are modified. 
   Next, a doctor blade method or printing method, for example, is used to apply the magnetic slurry onto a PET film or other support member, to form magnetic green sheets GS 1  serving as the magnetic layers A 1  to A 12  (see  FIG. 9 ). Also, the nonmagnetic slurry is applied to a PET film or other support layer using for example a doctor blade method or printing method, to form the nonmagnetic green sheets GS 2  serving as the nonmagnetic layers B 1  and B 2  (see  FIG. 6  to  FIG. 9 ). The thicknesses of these magnetic green sheets GS 1  and nonmagnetic green sheets GS 2  can be set to, for example, approximately 10 μm to 30 μm. Then, laser machining is performed to form through-holes TH (see FIG.  9 ) penetrating the magnetic green sheets GS 1  and nonmagnetic green sheets GS 2  in the thickness direction at prescribed positions, and the through-holes TH are filled with conductive paste. 
   Next, conductive paste is applied in a prescribed pattern onto the magnetic green sheet GS 1  which is to become the magnetic layer A 2 , and by drying for less than 1 hour at approximately 40° C. to 80° C., a strip-like conductive film serving as the conductor pattern C 1  and leading conductor D 1  is formed. Similarly, by applying conductive paste in a prescribed pattern onto the magnetic green sheet GS 1  which is to become the magnetic layer A 11 , a strip-like conductive film serving as the conductor pattern C 12  and leading conductor D 2  is formed. The thickness of the conductive films serving as these conductor patterns C 1  and C 12  and leading conductors D 1  and D 2  can be set to approximately 10 μm to 25 μm, and the widths of the conductive films serving as these conductor patterns C 1  and C 12  can be set to approximately 200 μm to 300 μm. 
   Next, the conductive films serving as the conductor patterns C 2  to C 11  and magnetic films serving as the magnetic films F 1  to F 10  are formed on the magnetic green sheets GS 1  which are to become the magnetic layers A 3  to A 10  and on the nonmagnetic green sheets GS 2  which are to become the nonmagnetic layers B 1  and B 2 . Specifically, as shown in  FIG. 6 , first conductive paste is applied in prescribed patterns onto the magnetic green sheets GS 1  which are to become the magnetic layers A 3  to A 10  and onto the nonmagnetic green sheets GS 2  which are to become the nonmagnetic layers B 1  and B 2 , and by drying for less than 1 hour at approximately 40° C. to 80° C., strip-like conductive films H 1  are formed. The thickness of these conductive films H 1  can be set to approximately 15 μm to 30 μm, and the width can be set to approximately 200 μm to 300 μm. 
   Then, magnetic slurry is applied so as to cover the edge portions H 1   a  of the conductive films H 1  and so as to expose the upper face of the center portions H 1   b  other than the edge portions H 1   a  of the conductive films H 1 , and by drying for less than 1 hour at approximately 40° C. to 80° C., magnetic films I 1  are formed. The thickness of these magnetic films I 1  is set to be greater than the thickness of the conductive films H 1 , and it is preferable that the thickness be set to approximately 20 μm to 40 μm. That is, the height of the magnetic films I 1  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the conductive films H 1  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . 
   It is preferable that the width T 1  of the edge portions H 1   a  of the conductive films H 1  be set to approximately 20 μm to 40 μm. It is preferable that the width T 2  of the center portions H 1   b  of the conductive films H 1  be set to approximately 150 μm to 270 μm. 
   Next, as shown in  FIG. 7 , conductive paste is applied, in the same pattern as the conductive films H 1 , onto the exposed faces of the conductive films H 1  and onto the magnetic films I 1 , and by drying for less than 1 hour at approximately 40° C. to 80° C., strip-like conductive films H 2  are formed. The thickness and width of the conductive films H 2  can be set to approximately the same values as for the conductive films H 1 . 
   Then, magnetic slurry is applied so as to cover the edge portions H 2   a  of the conductive films H 2  and so as to expose the upper face of the center portions  112   b  other than the edge portions H 2   a  of the conductive films H 2 , and by drying for less than 1 hour at approximately 40° C. to 80° C., magnetic films I 2  are formed. The thickness of these magnetic films I 2  is set to be greater than the thickness of the conductive films H 2 , and it is preferable that the thickness be set to approximately the same as the thickness of the magnetic films I 1 . That is, the height of the magnetic films I 2  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the conductive films H 2  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . 
   Next, as shown in  FIG. 7 , conductive films H 3 , magnetic films I 3 , conductive films H 4 , and magnetic films I 4  are formed, in this order, similarly to the conductive films H 2  and magnetic films I 2 . Hence, the height of the magnetic films I 4 , which are at the uppermost positions among the magnetic films I 1  to I 4 , from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 , is greater than the height of the conductive films H 4 , which are at the uppermost positions among the conductive films H 1  to H 4 , from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . 
   Next, as shown in  FIG. 8 , connection conductive paste is applied so as to form hemispherical shapes on the exposed faces of the conductive films H 4 , which are at the uppermost positions among the magnetic films I 1  to I 4 , and by drying for less than 1 hour at approximately 40° C. to 80° C., connection conductive films H 5  are formed. That is, the connection conductive films H 5  are not applied onto the magnetic films I 4 , but are formed only on end portions of the conductive films H 4 . 
   The height of the connection conductive films H 5  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the magnetic films I 4 , which are at the uppermost positions among the magnetic films I 1  to I 4 , from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . The thickness of the connection conductive films H 5  can be set to approximately 10 μm to 30 μm. 
   Next, the magnetic green sheets GS 1  which are to become the magnetic layers A 1  to A 12  and the nonmagnetic green sheets GS 2  which are to become the nonmagnetic layers B 1  and B 2  are laminated in the order shown in  FIG. 2 , and pressure is applied in the lamination direction to perform pressure-bonding, to form a green sheet laminate (not shown). At this time, as shown in  FIG. 9 , connection conductive films H 5  are crushed by the other green sheets which are adjacent in the lamination direction, and the connection conductive films H 5  are connected to the portions of the conductive films H 1  of the other green sheets which fill the interiors of through-holes TH in the other green sheets. 
   Next, after cutting the green sheet laminate into chip units, burning is performed for 10 hours or more at approximately 850° C. to 900° C., to fabricate laminates  12 . After burning, a laminate  12  has, for example, a length of approximately 2.5 mm, width of approximately 2.0 mm, and height of approximately 1.0 mm. As a result, the magnetic green sheets GS 1  become the magnetic layers A 1  to A 12 , the nonmagnetic green sheets GS 2  become the nonmagnetic layers B 1  and B 2 , the conductive films H 1  to H 4  become the various conductor patterns C 2  to C 11 , the magnetic films I 1  to I 4  become the various magnetic films F 1  to F 10 , and the connection conductive films H 5  become the various connection conductors G 1  to G 10 . The shrinkage rate during burning of the conductive films is set to for example approximately 15% to 25%, and the shrinkage rate during burning of the green sheets GS 1  and GS 2  and of the magnetic films is set to for example approximately 10% to 20%. Further, because the conductive paste and the connection conductive paste differ as explained above, the shrinkage rate during burning of the connection conductive films H 5  is smaller than the shrinkage rate during burning of the conductive films. 
   Next, external electrodes  14  and  16  are formed on this laminate  12 . By this means, a laminated inductor  10  is formed. The external electrodes  14  and  16  are formed by transferring a conductive paste, the main component of which is Ag, Cu or Ni, on both sides in the length direction of the laminate  12 , and then burning at a prescribed temperature (for example, 700° C. to 800° C.), and then performing electroplating. In electroplating, Cu, Ni or Sn can for example be used. 
   (Operation) 
   As described above, in this embodiment, the peripheral side faces S 3  of the conductor patterns C 2  to C 11  are concavo-convex faces in which concave portions and convex portions are arranged in alternation in the lamination direction, and a portion of the laminate  12  enters into the concave portions  18   a  of these peripheral side faces S 3 . Hence, due to the so-called anchor effect, there is extremely little tendency for separation of the portions of the laminate  12  in contact with the peripheral side faces S 3  of the conductor patterns from the concavo-convex shape peripheral side faces. As a result, even when the conductor patterns C 2  to C 11  are thick (20 μm or greater), there is extremely little tendency for cracking to occur in portions of the laminate  12  positioned between adjacent conductor patterns in the lamination direction. Hence, concerns about short-circuits between adjacent conductor patterns due to the migration phenomenon are greatly reduced. 
   Further, in this embodiment the tips of the convex portions  18   b  of the peripheral side faces S 3  have a tapered shape. Hence, portions of the laminate  12  in contact with the peripheral side faces S 3  of conductor patterns do not readily tend to separate from the concavo-convex shape peripheral side faces S 3 . 
   Further, between the portions of the areas S 1   b  excluding the portions in which connection conductors G 1  to G 10  are positioned (that is, the areas indicated by diagonal lines in  FIG. 3 ) and the laminate  12 , gaps V are formed. Hence, because the relative permittivity of air is normally lower than the relative permittivity of the laminate  12 , the distributed capacitance is small. As a result, losses at high frequencies can be made small. 
   Further, in this embodiment the conductor patterns C 2  to C 11  are connected to the through-hole conductors E 1  to E 10  respectively via the connection conductors G 1  to G 10 . And, when seen from the lamination direction, the connection conductors G 1  to G 10  are larger than the through-hole conductors E 1  to E 10 , and are positioned within the areas S 1   b  of the broad faces S 1  of the conductor patterns C 2  to C 11  in the non-overlapping portions  20   b . Hence, the conductor patterns C 2  to C 11  are reliably connected to the through-hole conductors E 1  to E 10  by the connection conductors G 1  to G 10 , respectively, so that connection reliability can be greatly improved. 
   Further, in this embodiment the height of the magnetic films I 4 , which are at the uppermost positions among the magnetic films I 1  to I 4 , from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the conductive films H 4 , which are at the uppermost positions among the conductive films H 1  to H 4 , from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . As a result, uniform pressure-bonding of the green sheet laminate as a whole is possible. Consequently, the occurrence of interlayer separation in the manufactured laminated inductor  10  can be adequately suppressed. 
   In a method of manufacture of laminated inductors of the prior art, an auxiliary magnetic material layers were formed surrounding the periphery of the conductor patterns on the magnetic green sheets, and had thicknesses greater than that of the conductor patterns (see for example Japanese Examined Patent Publication No. 7-123091). However, in a laminated inductor manufactured in this way, one of the broad faces among the broad faces of the strip-like conduction patterns became separated from the laminate. Hence, adjacent conductor patterns in the lamination direction were not electrically connected via through-hole conductors, and connection faults sometimes occurred. 
   On the other hand, formation on the magnetic green sheets of auxiliary magnetic material layers, surrounding the periphery of the conductor patterns, which are thinner than the thickness of the conductor patterns is also conceivable. However, in this case, the green sheet laminate as a whole, in which green sheets are laminated, cannot be subjected to uniform pressure bonding, and there has been the problem that interlayer separation occurs in laminated inductors manufactured in this way. 
   These methods of the prior art may be discussed in light of this embodiment as follows. That is, when the difference between the height from the magnetic green sheet GS 1  or nonmagnetic green sheet GS 2  of the conductive films H 4  positioned uppermost among the conductive films H 1  to H 4 , and the height from the magnetic green sheet GS 1  or nonmagnetic green sheet GS 2  of the magnetic films I 4  positioned uppermost among the magnetic films I 1  to I 4 , is stipulated as a protrusion amount X of the conductive film H 4  from the magnetic film I 4  (see (a) of  FIG. 10 ), then as shown in (b) of  FIG. 10 , the smaller the protrusion amount X, the higher is the rate of occurrence of line breakage, although the rate of occurrence of interlayer separation is decreased; on the other hand, the larger the protrusion amount X, the higher is the rate of occurrence of interlayer separation, although the rate of occurrence of line breakage is decreased. Hence, in the prior art it has been difficult to achieve both reduced occurrence of interlayer separation and a reduction in connection faults. 
   However, in the embodiment described above, the magnetic films I 1  to I 4  are formed so as to respectively cover the edge portions of the conductive films H 1  to H 4  while exposing the upper faces of the conductive films H 1  to H 4  other than the edge portions, and the height of the magnetic films I 4  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the conductive films H 4  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . For this reason, the protrusion amount X is small, and so the area of contact of a magnetic film I 4  formed on one green sheet with the green sheet adjacent to the one green sheet is increased, and together with the stronger pressing of the magnetic film I 4  and the other green sheet due to the edge portions of the conductive film H 4 , there is less tendency for interlayer separation in the laminated inductor  10 . Also, in this embodiment connection conductive films H 5  are formed on the exposed faces of conductive films H 4  positioned uppermost among the conductive films H 1  to H 4 , and the height of the connection conductive films H 5  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2  is greater than the height of the magnetic films I 4  from the magnetic green sheets GS 1  or nonmagnetic green sheets GS 2 . For this reason, when the magnetic green sheets GS 1  which become magnetic layers A 1  to A 12  and nonmagnetic green sheets GS 2  which become nonmagnetic layers B 1  and B 2  are laminated in the order shown in  FIG. 2 , the connection conductive films H 5  are crushed by the other green sheet adjacent in the lamination direction, so that the connection conductive films H 5  are reliably connected to the portion of the conductive film H 1  on the other green sheet which fills the through-hole TH in the other green sheet, and connection reliability is greatly improved. Hence, both reduced occurrence of interlayer separation and a reduction in connection faults can be achieved. 
   Further, in this embodiment, the shrinkage rate at the time of burning of the connection conductor films H 5  is lower than the shrinkage rate at the time of burning of the conductive films. Hence, during burning, there is little tendency for shrinkage of connection conductive films H 5 , so that even after burning, the connection between the conductive film H 4  on one green sheet and the portion of the conductive film H 1  on the other green sheet which fills the through-hole TH of the other green sheet can be reliably maintained. As a result, connection faults can be further reduced. 
   In the above, preferred embodiments of the invention have been explained in detail; however, the invention is not limited to the above-described embodiments. For example, in this embodiment the laminate  12  comprises the magnetic layers A 1  to A 12  and the nonmagnetic layers B 1  and B 2 ; however, the laminate is not limited to this configuration, and the entirety may be formed from magnetic material, or the entirety may be formed from nonmagnetic material. However, in order to suppress magnetic saturation and limit reductions in the inductance value when large currents flow, from the standpoint of further improving the DC superpositioning characteristics, it is preferable that, as in this embodiment, the laminate be configured with a nonmagnetic layer B 1  inserted between the magnetic layers A 4  and A 5 , and with a nonmagnetic layer B 2  inserted between the magnetic layers A 7  and A 8 . 
   Also, in these embodiments hemispherical connection conductive films H 5  are formed, and so the connection conductors G 1  to G 10  are cylindrical or have a truncated hemispherical shape; but other shapes may be used. That is, the connection conductors G 1  to G 10  may be square columns, truncated four-sided pyramids (four-sided frustums), three-sided columns, truncated three-sided pyramids (three-sided frustums), or various other shapes. 
   Further, in these embodiments four layers each of the conductive films H 1  to H 4  and magnetic films I 1  to I 4  were formed in alternation; however, from the standpoint of obtaining an anchor effect, it is sufficient to form two or more layers each of conductive films and magnetic films in alternation. 
   Further, in these embodiments four layers each of the conductive films H 1  to H 4  and magnetic films I 1  to I 4  were formed in alternation; however, from the standpoint of enhancing the reliability of connection by the connection conductors G 1  to G 10 , it is sufficient to form one or more layers each of conductive films and magnetic films in alternation. 
   Further, in these embodiments the convex portions  18   b  of the peripheral side faces S 3  had a tip shape which was tapered in moving in the direction away from the conductor patterns C 2  to C 11 ; but if the peripheral side faces S 3  are concavo-convex faces, the convexprotruding portions  18   b  need not be tapered. 
   It is apparent that various embodiments and modifications of the present invention can be embodied, based on the above description. Accordingly, it is possible to carry out the present invention in modes other than the above best modes, within the following scope of claims and the scope of equivalents thereto.