PATENT ABSTRACT
A multilayer ceramic substrate with an interlayered capacitor has a large electrostatic capacity and a high flexural strength, such as 1,500 Kg/cm 2  or more, and yet is manufactured at a relatively low firing or sintering temperature. A first ceramic body includes a plurality of laminated first ceramic sheets with a high dielectric constant and with a plurality of internal electrodes sandwiching the respective first ceramic sheets to form capacitors therebetween. A second ceramic body is laminated over one side of the first ceramic body and has a plurality of laminated second ceramic sheets with a low dielectric constant. A plurality of first wiring layers are sandwiched between the second ceramic sheets. A third ceramic body is laminated over the other side of the first ceramic body and has a plurality of laminated third ceramic sheets formed of the same ceramic material that is used to make the second ceramic sheets. The second and third ceramic bodies are thicker than the first ceramic body. A second embodiment of the invention is a hybrid ceramic structure made of glass-ceramic insulator layers sandwiching at least one dielectric layer with interposed circuit patterns formed thereon.

PATENT DESCRIPTION
BACKGROUND OF THE INVENTION 
     The present invention relates to a multilayer ceramic substrate having an interlayered capacitor. 
     A plurality of semiconductor chips are mounted directly on a multilayer ceramic substrate. Each semiconductor chip may be an IC or an LSI. A capacitor can be formed within the substrate by sandwiching an inner ceramic sheet between a pair of conductor layers. In such an integrated capacitor substrate, conductor pads are formed on the top sheet and wirings are formed within the substrate to connect the capacitor and the pads. 
     The capacitor substrate is manufactured by a green sheet laminating technique. According to this technique, green sheets are successively laminated and then are sintered or fired. The wirings are printed on each green sheet before the successive laminations. In a conventional green sheet laminating technique, alumina is used as the green sheet. The laminated green sheets must, therefore, be sintered at a sintering or firing temperature of 1,500° C. or higher. In view of the high sintering temperature, the wirings must be made of molybdenum, tungsten, or a like conductor material having a high melting point. 
     For such a high melting point conductor material, sintering must be carried out in a reducing atmosphere as, for example, in a hydrogen furnace. Due to the necessity of a high sintering temperature and a reduced atmosphere, the installation for manufacture is large scale, expensive, and objectionable from the viewpoint of energy saving. 
     The high melting point conductor material has a poor electrical conductivity. Each conductor for the wirings must, therefore, be relatively thick. This results in larger dimensions for the wirings. 
     Moreover, since all ceramic sheets are made of alumina, the dielectric constant is very low, say, nine or so, and a capacity of only about 3 pF/mm 2  can be obtained. 
     On the other hand, when a material having a high dielectric constant, such as steatite, forsterite, berium titanate, titanium dioxide, etc., can be used for the ceramic sheet instead of alumina, the mechanical strength of the substrate is low. Although, it can be utilized satisfactorily as a chip component, it is not acceptable for use as a circuit substrate. 
     It is mandatory, in general, for a multilayer substrate to have sufficient mechanical strength to support semiconductor chips and supporting structures mounted thereon. It is preferable that a multilayer substrate should have a flexural strength which is not less than 1,500 Kg/cm 2 . 
     SUMMARY OF THE INVENTION 
     It is, therefore, a principal object of the present invention to provide a multilayer ceramic substrate which can give a large electrostatic capacity. 
     It is another principal object of this invention to provide a multilayer ceramic substrate of the type described, which has a high flexural strength, such as 1,500 Kg/cm 2 , or more. 
     It is still another principal object of this invention to provide a multilayer ceramic substrate of the type described, which can be manufactured at a relatively low firing or sintering temperature. 
     It is a subordinate object of this invention to provide a multilayer glass-ceramic substrate of the type described, in which even nickel, chromium, or a like conductor material, can be used in fabricating wirings or circuit patterns. 
     It is another subordinate object of this invention to provide a multilayer glass-ceramic substrate of the type described, which can be manufactured even in an oxidizing atmosphere. 
     Other objects of this invention will become clear as the description proceeds. 
     According to this invention, a multilayer ceramic substrate has an interlayered capacitor. A first ceramic body has a pair of principal surfaces and includes a plurality of laminated first ceramic sheets with a high dielectric constant and with a plurality of internal electrodes sandwiching the respective first ceramic sheets to form capacitors therebetween. A second ceramic body is laminated over one of the principal surfaces of the first ceramic body and has a plurality of laminated second ceramic sheets with a low dielectric constant. A plurality of first wiring layers are sandwiched between the second ceramic sheets. A third ceramic body is laminated over the other of the principal surfaces of the first ceramic body and has a plurality of laminated third ceramic sheets formed of the same ceramic material that is used to make the second ceramic sheets. The thicknesses of the second ceramic body and of the third ceramic body are larger than the thickness of the first ceramic body. A plurality of external electrodes are provided on an external surface of the second ceramic body. 
     According to another aspect of this invention, a hybrid ceramic structure comprises a plurality of glass-ceramic insulator layers sandwiching at least one dielectric layer with interposed circuit patterns formed thereon. Each glass-ceramic insulator layer has a composition consisting essentially of oxides, as follows: 40 through 60 percent by weight of lead oxide, 1 through 30 percent by weight of boron oxide, 2 through 40 percent by weight of silicon dioxide, zero through 2.5 percent by weight of at least one oxide selected from oxides of chemical elements of Group I of the periodic table, 0.01 through 25 percent by weight of at least one oxide selected from oxides of chemical elements of Group II of the periodic table, and 0.01 through 10 percent by weight of at least one oxide selected from oxides of chemical elements of Group IV of the periodic table, except for carbon, silicon, and lead. 
     Preferably, the oxides of the Group I chemical elements are sodium and potassium. The oxides of the Group II chemical elements are magnesium oxide, calcium oxide, strontium oxide, barium oxide, and zinc oxide. The oxides of the Group IV chemical elements are zirconium dioxide, titanium dioxide, germanium dioxide, and stannic oxide. Briefly speaking, the multilayer substrate includes a pair of insulator layers of alumina ceramic containing boroxilicate-lead-glass and at least one high dielectric ceramic layer for making capacitors sandwiched between the insulator layers. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1(a) to FIG. 9(a) are plan views, at each process step, during the manufacture of a multilayer ceramic substrate sheets according to one embodiment of this invention; 
     FIG. 1(b) to FIG. 9(b) are sectional views of the same sheets, at each process step during the manufacture, corresponding to the steps shown in FIG. 1(a) to FIG. 9(a); 
     FIG. 10 is a sectional view of the laminate obtained at each process step during the manufacture, corresponding to FIG. 1 to FIG. 9; and 
     FIG. 11 is a sectional view of the laminate obtained by the second embodiment according to the present invention. 
    
    
     DESCRIPTION OF THE PREFERRED EMBODIMENTS 
     A multilayer ceramic substrate, according to a preferred embodiment of the present invention, is manufactured according to a conventional green sheet laminating technique. For this purpose, a composition is used which will later be described in detail. The composition is dispersed in a solvent together with an organic binder, to form a slurry. Each green sheet is formed with a uniform thickness from the slurry, by using the known doctor blading technique. 
     The green insulator sheet is punched to the desired size and utilized as green insulator sheets 20, as shown in FIGS. 1(a) and 1(b). A green resistor sheet 21 is then prepared, as shown in FIGS. 2(a) and 2(b). 
     Similarly, the green dielectric sheet formed as described above is punched to the desired size as shown in FIGS. 3(a) and 3(b) to obtain green dielectric sheets 22. Next, vertically-conducting through holes 23 are formed in the green insulator sheets 20 by means of either a punching or drilling process, as shown in FIGS. 4(a) and 4(b). The through holes 23 formed here can be reduced to a minimum of 100 μm in diameter. The through holes 23 provide for the conduction of the internal electrodes for the capacitors and are formed likewise in the green dielectric sheets 21 as shown in FIGS. 5(a) and 5(b). The green resistor sheet 21 is punched and cut to the desired size, as shown in FIGS. 6(a) and 6(b), to form green resistor sheet pieces 24 to ensure the desired resistance values. 
     Next, as shown in FIGS. 7(a) and 7(b), conductor layers 25 forming the signal wires and shield wires are applied by screen printing on the green insulator sheets provided with through holes 23. Conductors are embedded in the through holes. A paste consisting of an alloy including one or more metals such as gold, silver, palladium, and platinum is used for the conductors. 
     Similarly, conductors are formed in the through holes and their neighborhood, on the green insulator sheets. 
     Conductive layers are formed, to act as internal electrodes for the capacitors. These layers are formed on the green dielectric sheets 22 having the through holes 23, as shown in FIGS. 8(a) and 8(b). The conductor added in FIGS. 7(a) and 7(b) was formed by screen printing and was embedded in the through holes to provide connections to two electrodes, for each vertically disposed capacitor. The resistor sheet pieces 24 are punched and cut to the given size and are bonded or pasted by a hot press onto the green insulator sheets 20, as shown in FIGS. 9(a) and 9(b), to obtain unified sheets. 
     Next, as shown in FIG. 10, the sheets of FIGS. 7, 8 and 9, the green insulator sheets 20 of FIG. 1 are used to adjust the thickness of each sheet of the laminate. The green insulator sheets, in which conductors are formed in the through holes and their neighborhood, are built together at temperatures of 200° to 130° C. and pressures of 200 to 300 Kg/cm 2 . In FIG. 10, the structure is such that green insulator sheets 20 sandwich green dielectric sheets 22 which are piled up vertically. The green dielectric sheet portion and the conductor layers 26 are arranged vertically to become a capacitor formation portion 32 (indicated by a broken line in FIG. 10) after sintering. The capacitor is connected to conductor layers 33 for external terminals via the through holes 23 and the conductor layers. A green RuO 2  resistor sheet 24 forms a resistor portion 31 (also indicated by a broken line) by the lamination and sintering, which is lead outwardly by the through holes 23 and the conductor wires. The laminate thus obtained is cut to the desired size and sintered. 
     The sintering profile consists of three process steps: a binder removal step, a calcining step, and a sintering step. In the binder removal step, the laminate is held at a maximum of 400° C. for three hours; and in the calcination and sintering steps, a continuous furnace is used at 800° C. and 900° C., respectively. 
     This invention is effective enough to enable the fabrication of a multilayer ceramic hybrid substrate including resistors, capacitors, signal wires, shield layers, and other components by forming the resistors, dielectrics, insulators, and conductors and then sintering them simultaneously at a temperature in the range of 800° C. to 1000° C. 
     In view of flexural strength, it is preferable that the total thickness of laminated high dielectric ceramic sheets is smaller than that of laminated low dielectric ceramic sheets. 
     Preferred examples of the compositions and the multilayer ceramic substrates will now be described. 
     Powder of aluminum oxide and powder of borosilicate-lead series glass were weighed to provide various compositions listed below. The components are expressed as oxides, in percent by weight, and in Tables 1 and 2 as samples Nos. 1 through 54. In Table 1, the oxides of chemical elements of Groups I, II and IV of the periodic table are given, in totals, respectively, for each sample. The oxides of the Groups I, II and IV chemical elements are shown in detail in Table 2 for the respective samples, as numbered in Table 1. The percentages of components of each composition given in Tables 1 and 2 are within the limits of the composition specified hereinabove. 
     
                       TABLE 1______________________________________                         Oxide(s)                                Oxide(s)                                       Oxide(s)                         of Group                                of Group                                       of GroupSam-                          II ele-                                IV ele-                                       I ele-ple  Al.sub.2 O.sub.3        PbO    B.sub.2 O.sub.3                    SiO.sub.2                         ment(s)                                ment(s)                                       ment(s)______________________________________ 1   60      1.0    10.3 22.7 4.0    1.0    1.0 2   60      23.1   1.0  8.59 5.9    0.91   0.5 3   60      23.24  8.3  2.0  2.55   1.91   2.0 4   60      12.8   6.7  6.3  9.3    3.0    1.9 5   55      20.2   3.9  3.0  11.1   4.7    2.1 6   50      8.3    3.4  32.5 3.0    0.55   -- 7   50      10.0   5.0  28.3 6.1    0.6    -- 8   50      12.0   4.5  26.99                         0.01   5.5    1.0 9   50      9.5    8.3  7.3  20.0   2.9    2.010   50      22.0   15.4 6.49 4.0    0.01   2.111   50      10.7   8.3  4.7  15.0   10.0   1.312   50      20.1   3.8  16.4 2.7    5.0    2.013   50      32.1   3.5  7.2  6.2    1.0    --14   50      11.3   25.1 6.4  2.4    3.2    1.615   50      2.8    1.1  37.1 5.5    1.5    2.016   50      8.4    5.6  2.1  23.0   7.0    2.017   45      18.4   10.2 3.9  15.1   7.4    --18   40      14.5   13.6 2.5  23.0   4.6    1.819   40      11.0   16.4 12.8 12.7   7.1    --20   40      39.0   4.0  4.5  10.0   1.5    1.021   40      10.7   28.0 7.0  10.2   2.1    2.022   40      6.0    1.2  38.2 10.5   2.3    1.823   55      7.4    3.1  29.2 2.6    0.5    2.224   55      7.5    3.1  26.2 3.19   2.51   2.525   40      16.6   1.0  37.1 2.7    0.6    2.026   60      4.1    9.0  13.0 7.7    3.9    2.327   45      8.5    3.1  27.1 10.15  4.15   2.028   50      10.0   7.8  19.5 8.0    2.5    2.229   40      13.0   6.0  25.8 10.19  3.01   2.030   50      5.0    2.2  30.5 2.79   2.51   2.031   50      8.2    3.4  30.6 1.0    4.9    1.832   50      8.2    3.4  30.9 1.5    4.4    1.533   50      8.2    3.4  30.2 2.0    3.9    2.234   50      8.2    3.4  30.2 3.0    2.9    2.235   50      8.2    3.4  30.2 3.0    2.9    2.236   50      8.2    3.4  30.2 3.0    2.9    2.237   50      8.2    3.4  30.2 3.0    2.9    2.238   50      8.2    3.4  30.2 3.0    2.9    2.239   50      8.2    3.4  32.4 3.0    2.9    --40   50      8.2    3.4  32.4 3.0    2.9    --41   50      8.2    3.4  32.4 3.0    2.9    --42   50      8.2    3.4  30.2 3.0    2.9    2.243   50      8.2    3.4  32.4 3.0    2.9    --44   50      8.2    3.4  32.4 3.0    2.9    --45   50      8.3    3.4  30.2 3.0    2.9    2.246   50      8.3    3.4  30.2 3.0    2.9    2.247   50      8.3    3.4  32.4 3.0    2.9    --48   50      8.3    3.4  32.4 3.0    2.9    --49   50      8.3    3.4  32.4 3.0    2.9    --50   50      8.3    3.4  32.4 3.0    2.9    --51   50      8.3    3.4  32.4 3.0    2.9    --52   50      8.3    3.4  32.4 3.0    2.9    --53   50      8.3    3.4  32.4 3.0    2.9    --54   50      8.3    3.4  30.2 3.0    2.9    2.2______________________________________ 
    
     
                                           TABLE 2__________________________________________________________________________                            Oxide(s) ofOxide(s) of element(s)              Oxide(s) of element(s)                           element(s)of Group II        of Group IV  of Group ISample    MgO  CaO     SrO        BaO           ZnO              ZrO                 TiO.sub.2                    GeO.sub.2                        SnO.sub.2                           Na.sub.2 O                               K.sub.2 O__________________________________________________________________________ 1  1.1  2.4     -- 0.4           0.1              0.4                 0.6                    --  -- 0.5 0.5 2  0.3  4.0     -- 0.7           1.0              0.8                  0.01                    --  -- 0.5 -- 3  0.7   0.05     -- 0.5           1.3               0.01                 1.9                    --  -- 1.0 1.0 4  1.1  4.2     -- -- 4.0              1.1                 1.9                    --  -- 1.0 0.9 5  3.2  3.9     -- 1.6           2.4              1.5                 3.2                    --  -- 1.1 1.0 6  0.2  2.7     -- 0.1           --  0.45                 0.1                    --  -- --  -- 7  0.5  5.5     -- 0.1           -- 0.5                 0.1                    --  -- --  -- 8  --  0.01     -- -- -- 3.0                 2.5                    --  -- 1.0 -- 9  5.0  5.0     2.3        4.5           3.2              1.1                 1.8                    --  -- 1.5 0.510  0.3  0.2     1.1        0.1           0.5               0.01                 -- --  -- 1.1 1.011  4.2  8.0     1.9        0.6           0.3              5.0                 5.0                    --  -- 0.7 0.612  -- -- 1.5        1.2           -- 2.0                 3.0                    --  -- 1.0 1.013  -- -- 3.0        -- 3.2              -- 1.0                    --  -- --  --14  -- 2.4     -- -- -- -- 3.2                    --  -- 0.8 0.815  -- -- 4.0        1.5           -- 1.5                 -- --  -- 1.0 1.016  5.8  10.0     -- 7.2           -- 4.0                 3.0                    --  -- 1.0 1.017  10.0  1.5     -- 1.9           1.7              3.3                 4.1                    --  -- --  --18  3.7  6.3     -- 10.0           3.0              2.1                 2.5                    --  -- 0.9 0.919  3.2  7.1     -- 0.6           1.8              2.1                 5.0                    --  -- --  --20  -- 5.0     -- 3.0           2.0              0.5                 1.0                    --  -- 1.0 --21  1.6  3.0     -- 5.0           0.6              0.7                 1.4                    --  -- 1.0 1.022  2.3  2.2     -- 1.0           5.0              0.8                 1.5                    --  -- 0.9 0.923  0.2  2.3     -- 0.1           -- 0.4                 0.1                    --  -- 1.1 1.124  2.0  2.4     --  0.09           -- 2.3                  0.01                    --  -- 1.3 1.225  0.2  2.4     -- 0.1           -- 0.3                 0.3                    --  -- 1.0 1.026  2.2  5.0     -- 0.5           -- 2.5                 1.4                    --  -- 1.2 1.127  0.1  10.0     --  0.05           --  2.15                 2.0                    --  -- 1.0 1.028  4.3  1.2     -- 2.5           -- 1.5                 1.0                    --  -- 1.1 1.129  2.1  8.0     --  1.09           -- 2.0                  0.01                    --  -- 1.0 1.030  1.1  6.5     --  0.19           --  0.01                 2.5                    --  -- 1.0 1.031  1.0  -- -- -- -- 2.9                 2.0                    --  -- 0.9 0.932  -- -- 1.5        -- -- -- 2.4                    1.0 1.0                           1.0 0.533  -- -- -- 2.0           -- 1.0                 1.0                    --  1.9                           1.1 1.134  -- -- -- -- 3.0              -- 1.0                    1.0 0.9                           1.1 1.135  1.0  2.0     -- -- -- -- -- 2.9 -- 1.1 1.136  1.6  -- 1.4        -- -- -- -- --  2.9                           1.1 1.137  1.7  -- -- 1.3           -- -- -- 1.4 1.5                           1.1 1.138  0.9  -- -- -- 2.1              1.8                 -- --  1.1                           1.1 1.139  -- 2.3     0.7        -- -- 1.9                 -- 1.0 -- --  --40  -- 2.9     -- 0.1           -- -- 1.5                    1.4 -- --  --41  -- 2.2     -- -- 0.8              0.7                 -- 1.3 0.9                           --  --42  -- -- 1.6        -- 1.4              -- 1.0                    0.6 1.3                           1.1 1.143  -- -- -- 1.8           1.2              0.7                 0.7                    --  1.5                           --  --44  1.0  0.7     0.3        -- -- 1.3                 1.2                    0.4 -- --  --45  1.1  -- 0.9        1.0           -- 0.6                 1.1                    0.3 0.9                           1.1 1.146  1.3  -- 1.2        -- 0.5              0.6                 1.3                    0.5 0.5                           1.1 1.147  0.8  -- -- 0.5           1.7              0.6                 0.1                    1.3 0.9                           --  --48  -- 1.4     0.7        0.9           -- 0.6                 0.7                    1.3 0.4                           --  --49  -- 0.8     1.1        -- 1.1              1.5                 0.2                    0.6 0.6                           --  --50  -- -- 0.4        0.9           1.7              0.4                 1.6                    0.5 0.4                           --  --51  -- 0.7     0.9        0.9           0.5              0.7                 0.2                    0.9 1.1                           --  --52  0.5  -- 1.1        0.6           0.8              1.3                 0.3                    1.1 0.2                           --  --53  0.8  0.3     0.9        -- 1.0              0.4                 0.1                    1.1 1.3                           --  --54  0.6  0.7     1.3        0.4           -- 0.1                 1.9                    0.6 0.3                           1.1 1.1__________________________________________________________________________ 
    
     The weighed powders were blended or mixed in a ball mill, while wet, to provide a mixture. This blending continued during, for example, twenty-four hours. Together with an organic binder, the mixture was suspended in a solvent to form a slurry. The binder may be polyvinyl, butylal, polyvinyl alcohol, or an acrylic resin. The solvent may be ethylene glycol monoethyl ether. 
     Green sheets of a uniform thickness between 10 microns and 190 microns were formed from the slurry by a use of the known doctor blading technique. The green sheets of various uniform thicknesses were cut or blanked into rectangular sheets having a common area of 60 mm×40 mm. In compliance with the wirings to be formed for the semiconductor chips, through or via holes were formed through the rectangular sheets, by a punch and die. Conductor or metallic paste was applied onto the punched sheets by the known screen printing process. The conductor paste included gold, silver, platinum, palladium, copper, nickel, chromium, a gold palladium alloy, a silver gold alloy, a silver palladium alloy, or the like. 
     As for the green dielectric sheet, various ceramic compositions are listed in Table 3 as sample Nos. 101 through 122, and are expressed in percent by mole. 
     In Table 4, various resistor compositions are listed as samples Nos. 201 through 230, and are expressed in percent by weight. 
     
                                           TABLE 3__________________________________________________________________________                       Sintering                              DielectricSample    Dielectric (mol %)      Temperature                              Constant__________________________________________________________________________101 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 100                          880° C.                              6000102 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 50 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    50                         910° C.                              10000103 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 33 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    67                         950° C.                              18000104 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 20 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    80                      990    19000105 Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3 100                       1050   20000106 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 100                       860     200107 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 66 - PbTiO.sub.3 34                       900    4000108 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 60 - PbTiO.sub.3  40                       1000   7000109 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 50 - PbTiO.sub.3 50                       1050   10000110 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 99 - Pb(Mn.sup.1/3 *Me.sup.2/3)O.sub.31                      860     200111 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 65 - PbTiO.sub.3 34 - Pb(Mn.sup.1/3    *Me.sup.2/3)O.sub.3 1   900    3800112 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 58 - PbTiO.sub.3 40 - Pb(Mn.sup.1/2    *Me.sup.2/3)O.sub.3 2   950    5000113 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 50 - PbTiO.sub.3 49 - Pb(Mn.sup.1/2    *Me.sup.2/3)O.sub.3 1   1050   10000114 Pb(Fe.sup.2/3 W.sup.1/2)O.sub.3 36 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    62 -                    950    18000    Pb(Zn.sup.1/3 Nb.sup.2/3)O.sub.3 2115 Pb(Fe.sup.2/3 W.sup.1/2)O.sub.3 36 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    48 -                    890    14000    Pb(Zn.sup.1/3 Nb.sup.2/3)O.sub.3 16116 Pb(Fe.sup.2/3 W.sup.1/2)O.sub.3 36 - Pb(Fe.sup.1/2 Nb.sup.1/2)O.sub.3    32 -                    900    7000    Pb(Zn.sup.1/3 Nb.sup.2/3)O.sub.3 32117 Pb(Zn.sup.1/3 Nb.sup.2/3)O.sub.3 30 - Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3    70                      880    3400118 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 24 - PbTiO.sub.3 36 - Pb(Ni.sup.1/3    Nb.sup.2/3)O.sub.3 40   990    6000119 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 63 - PbTiO.sub.3 33 - Pb(Mg.sup.1/3    Nb.sup.2/3)O.sub.3 4    950    3500120 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 75 - PbTiO.sub.3 25                       950    10200121 Pb(Fe.sup.2/3 W.sup.1/3)O.sub.3 85 - PbTiO.sub.3 12 - Pb(Mn.sup. 1/3    *Me.sup.2/3)O.sub.3 3   920    2680122 Pb(Mg.sup.1/2 W.sup.1/2)O.sub.3 54 - PbTiO.sub.3 23 - PbZrO.sub.3                       1000   1800__________________________________________________________________________ *Me: Nb, Ta, Sb 
    
     
                       TABLE 4______________________________________                           SheetSam-                            resistanceple  Resistor (wt %)            (Ω/□)______________________________________201   RuO.sub.2 5 - frit 95     ∞202  RuO.sub.2 20 - frit 80     3 × 10.sup.3203  RuO.sub.2 90 - frit 10     2204  Bi.sub. 2 Ru.sub. 2 O.sub.7 30 - frit 70                           ∞205  Bi.sub. 2 Ru.sub. 2 O.sub.7 65 - frit 45                           10.sup.6206  Bi.sub. 2 Ru.sub. 2 O.sub.7 95 - frit 5                           30.sup.207  Gd.sub. 2 Ru.sub. 2 O.sub.7 20 - frit 80                           ∞208  Gd.sub. 2 Ru.sub. 2 O.sub.7 45 - frit 55                           3 × 10.sup.5209  Gd.sub. 2 Ru.sub. 2 O.sub.7 95 - frit 5                           10.sup.4210  Pb.sub. 2 Ru.sub. 2 O.sub.6 10 - frit 90                           ∞211  Pb.sub. 2 Ru.sub. 2 O.sub.6 40 - frit 60                           2 × 10.sup.3212  Pb.sub. 2 Ru.sub. 2 O.sub.6 95 - frit 5                           2 × 10.sup.2213  RuO.sub.2 35 - Bi.sub. 2 Ru.sub. 2 O.sub.7 35 - frit                           80214  RuO.sub.2 25 - Bi.sub. 2 Ru.sub. 2 O.sub.7 25 - frit                           10.sup.3215  RuO.sub.2 10 - Bi.sub. 2 Ru.sub. 2 O.sub.7 30 - frit                           10.sup.6216  RuO.sub.2 35 - Gd.sub. 2 Ru.sub. 2 O.sub.7 35 - frit                           2 × 10.sup.2217  RuO.sub.2 20 - Gd.sub. 2 Ru.sub. 2 O.sub.7 20 - frit                           3 × 10.sup.4218  RuO.sub.2 10 - Gd.sub. 2 Ru.sub. 2 O.sub.7 20 - frit                           10.sup.5219  RuO.sub.2 45 - Gd.sub. 2 Ru.sub. 2 O.sub.7 45 - frit                           70.sup.220  Bi.sub. 2 Ru.sub. 2 O.sub.7 35 - Gd.sub. 2 Ru.sub. 2 O.sub.7 35 -frit 30                    10.sup.3221  Bi.sub. 2 Ru.sub.  2 O.sub.7 30 - Gd.sub. 2 Ru.sub. 2 O.sub.7 15 -frit 55                    10.sup.7222  Bi.sub. 2 Ru.sub. 2 O.sub.7 50 - Gd.sub. 2 Ru.sub. 2 O.sub.7 45 -frit 5                     3 × 10.sup.2223  RuO.sub.2 35 - Pb.sub. 2 Ru.sub. 2 O.sub.6 35 - frit                           50.sup.224  RuO.sub.2 10 - Pb.sub. 2 Ru.sub.2 O.sub.6 20 - frit                           2 × 10.sup.4225  RuO.sub.2 40 - Pb.sub. 2 Ru.sub. 2 O.sub.6 50 - frit                           20.sup.226  RuO.sub.2 63 - Bi.sub. 2 Ru.sub. 2 O.sub.7 3.5 - Gd.sub. 2 Ru.sub. 2O.sub.7 3.5 - frit 30      7227  RuO.sub.2 35 - Bi.sub. 2 Ru.sub. 2 O.sub.7 21 - Gd.sub. 2 Ru.sub. 2O.sub.7 14 - frit 30       70.sup.228  RuO.sub.2 7 - Bi.sub. 2 Ru.sub.  2 O.sub.7 14 - Gd.sub. 2 Ru.sub. 2O.sub.7 49 - frit 30       2 × 10.sup.3229  RuO.sub.2 10 - Bi.sub. 2 Ru.sub. 2 O.sub.7 20 - Gd.sub. 2 Ru.sub. 2O.sub.7 10 - frit 60       10.sup.6230  RuO.sub.2 10 - Pb.sub. 2 Ru.sub. 2 O.sub.6 15 - Bi.sub. 2 Ru.sub. 2O.sub.7 10 - frit 65       2 × 10.sup.6______________________________________  The numbers of laminated green sheets are listed below in Table 5 for the respective samples, as numbered in Tables 1 and 2. After being hot compressed, the laminates were shaped as desired by a cutter. Each shaped laminate was sintered in air for one hour at a sintering or firing temperature between 700° C. and 1,400° C. as listed in Table 5 in °C. Before attaining the sintering temperature, the binder was completely removed or burnt out by maintaining each shaped laminate at about 500° C. in the non-reducing atmosphere for five hours. 
    
     In Table 5, the numbers of innerlayered components are also shown. Metals listed in Table 5 for the circuit patterns are only gold, silver, platinum, palladium, nickel, chromium, a gold palladium alloy, a gold platinum alloy, and a silver palladium alloy. Other alloys mentioned above have also been used. 
     Table 5, furthermore, lists capacities of innerlayered capacitor, and the flexural strength, in F and Kg/cm 2 , respectively. Table 5 additionally shows the occurrence of peeling off in the multilayer substrate and dielectric constant of the dielectric layer after the sintering process. 
     
                                           TABLE 5__________________________________________________________________________          Number of  Number of          Green Sheets                     Internal              Flexural   Sintering   Dielectric                     Elements                           Dielectric                                 Capacity  Strength                                                PeelingSample  Temperature          Insulator               Layer R  C  Constant                                 (F)  Metal                                           (Kg/cm.sup.2)                                                Off__________________________________________________________________________ 1  212109     1400° C.          20   4     10 3  1500  0.2μ                                      Pt   1000 occured 2  204110   970    15   2     10 5   40   50 n Ag--Pd                                           2000 &#34; 3  223122   930    23   6     10 10  600  0.1μ                                      Au   1100 &#34; 4  226113   1150   20   10    10 15 2200  0.8μ                                      Au--Pd                                           1300 &#34; 5  211110   1050   10   7     13 7   30   0.1μ                                      Pd   1600 &#34; 6  230109   1000   13   3     12 8  3000  0.2μ                                      Au   2800 none 7  201118   980    30   3      4 8  2100  0.5μ                                      Ag--Pd                                           3000 &#34; 8  225103   950    25   3     15 8  2700  0.6μ                                      Au--Pt                                           2500 &#34; 9  205103   950    23   3      9 8  2800  0.6μ                                      Au   2600 &#34;10  215121   930    14   2      9 8  1300  0.3μ                                      Ag   2300 &#34;11  202114   930    20   5      3 20 3100  0.2μ                                      Ag--Pd                                           2400 &#34;12  202116   910    40   4      6 10 2500  0.8μ                                      Ag--Pd                                           2000 &#34;13  216102   910    35   4     12 10 3000  0.5μ                                      Au   2600 &#34;14  212111      910° C.          29   4     12 3  2100  0.6μ                                      Au   2200 &#34;15  203115   900    17   4     12 3  2400  0.7μ                                      Au   2400 &#34;16  229116   900    37   4      7 5  2000  0.6μ                                      Ag   2300 &#34;17  212110   850    45   5     12 5   80   80 n Ag--Pd                                           2500 &#34;18  220106   830    11   3      8 9   100  30 n Ag--Pd                                           2700 &#34;19  222105   790     7   5      4 6   900  0.1μ                                      Ag   1900 occured20  228109   500    15   1     19 6   600  80 n Au--Pt                                           2200 &#34;21  217101   810    40   6     17 4  1500  0.2μ                                      Ag--Pd                                           2000 none22  207121   920    53   5     20 8  1400  0.2μ                                      Ag--Pd                                           2100 &#34;23  206102   900    22   3     20 10 2500  20 n Ag   3300 &#34;24  227103   900    29   5     30 7  2700  0.5μ                                      Ag   3400 &#34;25  208107   900    15   7     20 8  2000  0.7μ                                      Ag--Pd                                           3000 &#34;26  214112   950    31   9     10 22 2300  0.1μ                                      Au   3100 &#34;27  221115   880    13   4     36 10 3000  50 n Ag   3100 &#34;28  224117      880° C.           5   2      6 4  1800  0.15μ                                      Ag   2900 &#34;29  228115      850° C.          19   1     13 5  2500  20 n Ag--Pd                                           2800 &#34;30  226101      890° C.          36   3     39 9  2000  0.1μ                                      Au   3000 &#34;31  223122   1000   22   3     22 8  1000  40 n Au--Pt                                           2500 &#34;32  209112   970    29   4     18 2  1800  0.4μ                                      Ag--Pd                                           2200 &#34;33  210108   970    47   4     10 10 3000  0.2μ                                      Ag--Pd                                           2300 &#34;34  220106   970    19   5     10 9   50   5 n  Ag--Pd                                           2400 occured35  219105   950    27   6     21 9  3000  0.6μ                                      Au   1500 &#34;36  202121   960    13   2     25 5  1000  0.1μ                                      Au   2200 none37  217122   960    17   2      4 5  1100  0.15μ                                      Ag   2100 &#34;38  214104   960    17   2     11 10 3200  0.4μ                                      Ag--Pd                                           2500 &#34;39  209114   960    23   4      9 9  2800  0.9μ                                      Ag--Pd                                           2800 &#34;40  204115   900    59   5     30 12 2900  1.2μ                                      Ag   2400 &#34;41  210111   900    70   3      7 6  1300  0.3μ                                      Ag   2600 &#34;42  223107      900° C.          45   4     11 7  2000  0.6μ                                      Ni   2500 &#34;43  230102   900    41   2     13 7  2400  0.3μ                                      Ni   2600 &#34;44  215112   940    43   4     12 10 2000  0.4μ                                      Ni   2600 &#34;45  205120   940    20   4     40 8  3100  1.1μ                                      Ni   2400 &#34;46  216103   940    17   5     16 8  3000  0.8μ                                      Cr   2500 &#34;47  224103   940    31   3     12 13 3100  0.7μ                                      Cr   2700 &#34;48  208109   940    31   5     20 10 2600  0.5μ                                      Cr   1700 occured49  212108   940    40   5     10 6  2800  1.5μ                                      Cr   2400 none50  218119   950    27   2      9 8  1300  0.3μ                                      Cr   2300 &#34;51  211121   950    51   9      9 20 1100  0.2μ                                      Ag   2600 &#34;52  226108   950    36   3     10 6  2700  0.4μ                                      Ag--Pd                                           2600 &#34;53  204120   950    23   2     15 8  2900  0.4μ                                      Au   2800 &#34;54  219113   950    29   4      9 8  2300  0.3μ                                      Ag--Pd                                           1300 occured__________________________________________________________________________ 
    
     The present invention is not restricted to the structure shown in FIG. 10. For example, as shown in FIG. 11, external terminals are provided on both sides of the laminate. In this case, both the upper and lower surfaces of the laminate can be utilized effectively; therefore, the multilayer ceramic composite thus obtained has the advantage of a miniaturized structure with a higher density. 
     A capacitor is formed in the hybrid substrate containing capacitors, resistors, and conductors. In the example of this invention, the substrate has a capacity of about 1 nF/mm 2  ; however, a capacitor of 10 μF maximum is formed, as an example. For a high dielectric material, a material which can be sintered at 850° C. to 950° C. or so can also be used, other than the composites listed on Table 3. 
     As described above, the multilayer ceramic hybrid substrate containing capacitors, resistors, and conductor wiring according to this invention can be sintered simultaneously at a low temperature in the range of 800° C. to 1000° C. in an oxidizing atmosphere, to form the plurality of capacitors. In addition, a miniature, high-density component containing a large-capacity capacitor, or a high-density, large mounting area, hybrid substrate with a satisfactorily high mechanical strength can be obtained. An improvement in the working efficiency and reliability can be realized by simplifying the process and reducing the cost. A high-conductivity conductor can also be utilized. 
     Furthermore, the multilayer hybrid substrate of this invention can be utilized in various electronic circuits for TV tuners, FM tuners, automobiles and other applications. 
     Those who are skilled in the art will readily perceive how to modify the invention. Therefore, the appended claims are to be construed to cover all equivalent structures which fall within the true scope and spirit of the invention.