Abstract:
An amplifier integrated circuit element or J-FET is used for impedance conversion and amplification of ECM. The amplifier integrated circuit element has advantages of allowing an appropriate gain to be set by adjusting a circuit constant, and of producing a higher gain than the J-FET; but also has a problem of having a complicated circuit configuration and requiring high costs. Using only the J-FET has also problems of outputting a voltage insufficiently amplified and producing a low gain. Against this background, provided is a discrete element in which: a J-FET and a bipolar transistor are integrated on one chip; a source region of the J-FET is connected to a base region of the bipolar transistor; and a drain region of the J-FET is connected to a collector region of the bipolar transistor. Accordingly, an ECM amplifying element with high input impedance and low output impedance can be achieved.

Description:
This application claims priority from Japanese Patent Application Number JP2008-086638, filed on Mar. 28, 2008, the content of which is incorporated herein by reference in its entirety. 
     BACKGROUND OF THE INVENTION 
     1. Field of the Invention 
     The present invention relates to an amplifying element and a manufacturing method thereof, and particularly to an amplifying element that is preferably used for an amplifying device and a manufacturing method thereof. 
     2. Description of the Related Art 
     In order to perform impedance conversion and amplification of an electret condenser microphone (hereinafter referred to as ECM), a junction field effect transistor (hereinafter referred to as J-FET) or an amplifier integrated circuit element is used, for example (see Japanese Patent Application Publications Nos. 2003-243944 and Hei 5-167358, for example). 
       FIG. 11  is a circuit diagram showing a conventional ECM  115  and an amplifying element  110  to be connected thereto. One end of the ECM  115  is connected to a gate G of the J-FET  110  which is the amplifying element. One end of the J-FET  110  is grounded, while the other end thereof is connected to a load resistance RL. Since the ECM  115  has high output impedance, a weak output current is stored in the gate G of the J-FET  110  for impedance conversion and is inputted as an input voltage. The input voltage is amplified and then a drain current with low output impedance flows from the J-FET  110 . The product of a change in the drain current and the load resistance RL is extracted as an AC component of an output voltage V out . The sensitivity of a microphone for the ECM  115  is better as the AC component of the output voltage V out  is larger. 
     In addition, in place of the above J-FET  110 , an amplifier integrated circuit element using C-MOS or Bi-CMOS is also well-known (see, for example, Japanese Patent Application publication No. Hei 5-167358). 
     The amplifier integrated circuit element has advantages that an appropriate gain of the circuit element can be selectively set by adjusting a circuit constant, and that the amplifier integrated circuit element generally produces a higher gain than the J-FET. However, the amplifier integrated circuit element has a problem of having a complicated circuit configuration and of requiring high costs. 
     On the other hand, it is known that the J-FET has high input impedance, causes only a small amount of low-frequency noise for small signal amplification, and is excellent in a high-frequency characteristic. In addition, the J-FET has a simpler circuit configuration and requires lower cost than the amplifier integrated circuit element. 
     Since the amplifier integrated circuit element amplifies an input together with input noise, S/N, which is an index of sound quality, is not improved even when the gain is changed. Additionally, the noise is generated from each of resistances and semiconductors. For this reason, having a more complicated circuit configuration than the J-FET with a simple configuration, the amplifier integrated circuit element includes a larger number of noise resources, and accordingly has a lower S/N than the J-FET, in general. Accordingly, it is a common practice to use the amplifier integrated circuit element if high sensitivity is required to be achieved, but to use the J-FET if the required sensitivity is achievable by the J-FET. 
     However, there is a problem that the J-FET alone cannot sufficiently amplify an output, so that the resultant gain is low. As described above, the sensitivity of the ECM microphone is influenced by the AC component of the output voltage V out  amplified by the amplifying element. Accordingly, a higher gain is desirable to improve the sensitivity of microphone. 
     In order to increase the gain, it is effective to increase the area (cell size) of the J-FET. However, the increase in the area of the J-FET leads to an increase in an input capacitance Cin of the J-FET. 
       FIG. 12  shows an equivalent circuit in an output unit of the ECM and an input unit of the J-FET. In  FIG. 12 , VAC is an AC output voltage at the time of releasing an output of the ECM, Cm is an internal capacitance of the ECM, and Cin is an input capacitance of the J-FET. 
     At this time, the output of the ECM is not released and Cin is in a loaded state. As expressed by the equation of Vin=Cm/(Cm+Cin)VAC, the input voltage Vin of the J-FET in this case becomes smaller as Cm becomes smaller or Cin becomes larger, thereby causing an input loss. Here, if the input loss is reduced, the gain can be increased. Accordingly, the increase of Cm in designing the ECM unit and the reduction of Cin in designing the amplifying element lead to an improvement in the gain. 
     However, in order to decrease the input capacitance Cin as described above, the area of the J-FET has to be reduced. In this case, the J-FET is capable of controlling only a reduced amount of current, thereby producing only a small gain. In other words, the gain and the input capacitance Cin have a trade-off relationship. Thus, the simple and reasonable amplifying element using the J-FET has a limitation in improving the gain. 
     SUMMARY OF THE INVENTION 
     The invention provides an amplifying element to be connected to an electret condenser microphone. The amplifying element includes a semiconductor substrate of a first general conductivity type, a semiconductor layer of the first general conductivity type formed on the semiconductor substrate, a junction field effect transistor formed on the semiconductor substrate and a bipolar transistor formed on the semiconductor substrate. The junction field effect transistor includes a back gate diffusion region of a second general conductivity type formed in the semiconductor layer, a back gate contact region of the second general conductivity type formed in the back gate diffusion region, a channel region of the first general conductivity type formed in the back gate diffusion region, a source region and a drain region of the first general conductivity type that are formed in the channel region, and a top gate region of the second general conductivity type formed in the channel region. The bipolar transistor uses the semiconductor substrate and the semiconductor layer as a collector region and includes a base region of the second general conductivity type formed in the semiconductor layer, and an emitter region of the first general conductivity type formed in the base region. The source region is electrically connected to the base region, and the drain region is electrically connected to the collector region. 
     The method also provides a method of manufacturing an amplifying element to be connected to an electret condenser microphone. The method includes forming a semiconductor layer of a first general conductivity type on a semiconductor substrate of the first general conductivity type, forming in the semiconductor layer a back gate diffusion region and a base region that are of a second general conductivity type, forming a channel region of the first general conductivity type in the back gate diffusion region and an emitter region of the first general conductivity type in the base region, forming a top gate region of the second general conductivity type in the channel region, forming in the channel region a source region and a drain region that are of the first general conductivity type, electrically connecting the source region and the base region, and electrically connecting the drain region and the collector region. 
     The invention further provides an electret condenser microphone system that includes an electret condenser microphone having a first terminal and a second terminal and an amplifying element including a semiconductor substrate, a junction field effect transistor formed on the semiconductor substrate and a bipolar transistor formed on the semiconductor substrate. The first terminal of the electret condenser microphone is connected to the gate of the junction filed effect transistor, the source of the junction field effect transistor is connected to the base of the bipolar transistor, and the drain of the junction filed effect transistor is connected to the collector of the bipolar transistor. The system also includes a load resistor connected to the collector of the bipolar transistor. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1  is a circuit diagram for illustrating an amplifying element according to a preferred embodiment; 
         FIG. 2  is a cross-sectional view for illustrating the amplifying element according to the preferred embodiment; 
         FIG. 3  is a plan view for illustrating the amplifying element according to the preferred embodiment; 
         FIG. 4  is a cross-sectional view for illustrating a method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 5  is a cross-sectional view for illustrating the method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 6  is a cross-sectional view for illustrating the method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 7  is a cross-sectional view for illustrating the method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 8  is a cross-sectional view for illustrating the method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 9  is a cross-sectional view for illustrating the method of manufacturing an amplifying element according to the preferred embodiment; 
         FIG. 10  is a circuit diagram for illustrating the amplifying element according to the preferred embodiment; 
         FIG. 11  is a circuit diagram for illustrating a conventional amplifying element; and 
         FIG. 12  is a circuit diagram for illustrating the conventional amplifying element. 
     
    
    
     DESCRIPTION OF THE INVENTION 
     By referring to  FIGS. 1 to 10 , a preferred embodiment of the present invention will be described by taking, as an example, the case where an n channel type J-FET and an npn bipolar transistor are integrated on an n type semiconductor substrate. 
       FIG. 1  is a circuit diagram showing a connection example of an amplifying element  10  according to the preferred embodiment. 
     The amplifying element  10  is an element that is connected to an electret condenser microphone (ECM)  15  so as to perform impedance conversion and amplification. In the amplifying element  10 , a junction field effect transistor (J-FET)  20  and a bipolar transistor  30  are integrated on a one conductivity type semiconductor substrate. 
     The ECM  15  has a vibration film (diaphragm) and an electrode facing thereto, which are arranged in a casing, and takes movements of the vibration film generated by sounds as changes in capacitance between the vibrating film and the electrode. The vibration film is configured of, for example, a polymeric material, and is allowed by the electret effect to sustain electric charges. 
     The amplifying element  10  according to the embodiment is a discrete (discrete semiconductor) element in which the J-FET  20  and the bipolar transistor  30  are integrally mounted on one chip. The discrete (discrete semiconductor) element is also called an individual semiconductor and is a collective term for simple-function semiconductor elements. One end of the ECM  15  is connected to a gate of the J-FET  20 . One end of the J-FET  20  (for example, a source S) is connected to a base B of the bipolar transistor  30  and the other end (for example, a drain D) of the J-FET  20  is connected to a collector C of the bipolar transistor  30 . The collector C of the bipolar transistor  30  is connected to power source a VDD through a load resistance RL. An emitter E of the bipolar transistor  30  is grounded. 
     The operation of the amplifying element  10  is as follows. 
     When power is supplied from the collector of the bipolar transistor  30 , a current i flows between the drain D and source S of the J-FET  20 . A capacitance change (voltage change) of the ECM  15  is applied to the gate G of the J-FET  20  as a gate voltage, so that the current i flowing through the J-FET  20  is controlled according to an amount of the capacitance change. The current i according to the capacitance change flows from the source of the J-FET  20  to the base B of the bipolar transistor  30  and a current is supplied to the bipolar transistor  30 . As a result, the current i is amplified by a current amplification factor β (=ΔIc/ΔIB=hfe) between the collector C and the emitter E. The result of the current amplification is converted to a voltage by the load resistance RL, and thus can be extracted from the collector C of the bipolar transistor  30  as an AC component of an output voltage V out . 
     In general, the J-FET  20  has high input impedance. Accordingly, even if the flow of charges (current) according to the capacitance change of the ECM  15  is weak, the flow of charges can be extracted as a voltage change. 
     In addition to this, in the embodiment, the occupancy area (cell size) of the J-FET  20  on one chip is set to be small (for example, about a tenth part of the occupancy area (cell size) of the bipolar transistor  30 ). Accordingly, an input capacitance Cin of the J-FET  20  is sufficiently small. 
     Accordingly, an input loss in the J-FET  20  can be largely reduced in relation to the capacitance change output from the ECM  15  (see,  FIG. 12 ). 
     On the other hand, when the cell size of the J-FET  20  is small, there is a problem that a gain becomes small. In the embodiment, however, an output current of the J-FET  20  can be amplified by the bipolar transistor  30 . In other words, a desired gain can be secured by appropriately selecting the current amplification factor β of the bipolar transistor  30 . 
     As described above, the amplifying element  10  according to the embodiment can include the high input impedance by the J-FET  20  and the low output impedance by the bipolar transistor  30  at the same time. Accordingly, as compared with an amplifier integrated circuit element using BIP-LSI, C-MOS-LSI, or Bi-C-MOS-LSI, an amplifying element with a simple manufacturing process and lower cost can be provided. 
     In addition, the discrete element has an advantage that the number of noise sources is small because the circuit is simple and the cost is low. 
     By referring to  FIG. 2 , the structure of the amplifying element  10  will be described by using an n type substrate as an example.  FIG. 2  is a schematic cross-sectional view of the amplifying element  10 . 
     The amplifying element  10  is a discrete element in which the J-FET  20  and the bipolar transistor  30  are integrated on an n type substrate SB. 
     The substrate SB has an n− type semiconductor layer  12  laminated on a high concentration n type semiconductor substrate  11  serving as a collector region of the bipolar transistor  30 . 
     The J-FET  20  includes a back gate diffusion region  21 , a channel region  22 , a back gate contact region  23 , a top gate region  24 , a source region  25 , and a drain region  26 . 
     The back gate diffusion region  21  is a p type impurity region provided in the surface of the n− type semiconductor layer  12 . The channel region  22  is an n type impurity region provided in the surface of the back gate diffusion region  21 . In the surface of the back gate diffusion region  21  outside the channel region  22 , the back gate contact region  23 , which is a high concentration p type impurity region, is provided. In the surface of the channel region  22 , the top gate region  24 , which is a high concentration p type impurity region, is provided, while the source region  25  and the drain region  26 , which are high concentration n type impurity regions, are provided on both sides of the top gate region  24 . 
     It is noted that conductivity types such as n+, n and n− belong in one general conductivity type and conductivity types such as p+, p and p− belong in another general conductivity type. 
     The bipolar transistor  30  is configured of a base region  31  and an emitter region  32  by using the substrate SB as a collector region. 
     The base region  31  is a p type impurity region provided in the surface of the n− type semiconductor layer  12 . The emitter region  32  is an n type impurity region provided in the surface of the base region  31 . In the surface of the emitter region  32 , an emitter contact region  35 , which is a high concentration type impurity region, is provided. In addition, a base contact region  34 , which is a high concentration p type impurity region, is provided in the surface of the base region  31 . 
     A collector extraction region  33  is an n type impurity region provided in the surface of the n− type semiconductor layer  12  with being spaced apart from the base region  31 . The collector extraction region  33  is provided with an impurity concentration higher than that of the n− type semiconductor region  12  in order to extract a current of the substrate SB serving as a collector region. In the surface of the collector extraction region  33 , a collector extraction contact region  36 , which is further higher concentration n type impurity region, is provided. 
     It is preferable that the collector extraction region  33  be connected to n type semiconductor substrate  11 . 
     On the surface of the substrate SB (the n− type semiconductor layer  12 ), a first electrode layer  40  forms a back gate electrode (BG)  41  and a top gate electrode (TG)  42 , which are respectively connected to the back gate contact region  23  and the top gate region  24 . 
     In addition, on the surface of the substrate SB (the n− type semiconductor layer  12 ), a second electrode layer  50  forms an emitter electrode (E)  51 , which is connected to the emitter contact region  35 . 
     Furthermore, on the surface of the substrate SB (the n− type semiconductor layer  12 ), a first wiring layer  60  forms a drain electrode (D)  61  and a collector wiring (C)  62  of the J-FET  20 , which are respectively connected to the drain region  26  and the collector extraction contact region  36 . 
     In addition, a second wiring layer  70  provided on the surface of the substrate SB forms a source electrode (S)  71  of the J-FET  20  and a base electrode (B)  72  of the bipolar transistor  30 , which are respectively connected to the source region  25  and the base contact region  34 . 
     On the back surface of the substrate SB, the third electrode layer forms a back surface collector electrode (C)  80 . 
       FIG. 3  is a plan view showing the patterns of the first and second electrode layers and the first and second wiring layers. The cross-sectional view taken along the a-a line in  FIG. 3  corresponds to the cross-sectional view in  FIG. 2 . 
     The first electrode layer  40  constitutes the comb-shaped back gate electrode  41 , the top gate electrode  42 , and a gate pad electrode  43 . The back gate electrode  41  and the top gate electrode  42  are respectively superimposedly disposed on the back gate contact region  23  and the top gate region  24 . 
     The second electrode layer  50  constitutes the comb-shaped emitter electrode  51  and an emitter pad electrode  52 . The emitter electrode  51  is superimposedly disposed on the emitter region  32  (the emitter contact region  35 ). 
     The first wiring layer  60  constitutes the drain electrode  61  and the collector wiring  62 . One end of the first wiring layer  60  is superimposedly disposed on the drain region  26  as the drain electrode  61  and the other end thereof is disposed on the collector extraction region  33  (the collector extraction contact region  36 ) as the collector wiring  62 . 
     The second wiring layer  70  constitutes the source electrode  71  and the base electrode  72 . The base electrode  72  is patterned in a comb shape. The source electrode  71  and the base electrode  72  are respectively superimposedly disposed on the source region  25  and the base region  31  (the base contact region  34 ). 
     Each of the drain electrode  61  and the source electrode  71  is disposed between the comb-shaped teeth of the back gate electrode  41  and the top gate electrode  42 . The base electrode  72  and the emitter electrode  51  are disposed in such a shape that the comb-shaped teeth thereof would be engaged with each other. 
     With this configuration, the source region  25  of the J-FET  20  and the base region  31  of the bipolar transistor  30  are electrically connected to each other. Accordingly, configured is the one-chip amplifying element  10  in which the drain region  26  of the J-FET  20  and the collector region (the collector extraction contact region  36 ) of the bipolar transistor  30  are electrically connected to each other (see  FIG. 2 ). 
     The amplifying element  10  according to the embodiment has the occupancy area (cell size) of the J-FET  20  on one chip, which is smaller than the occupancy area (cell size) of the bipolar transistor  30 . The ratio of the areas of the J-FET  20  to the bipolar transistor  30  is, for example, 1 to 10 or larger. 
       FIG. 3  shows the case where the J-FET  20  has one minimum unit cell configured of one pair of the source region  25 , the top gate region  24 , and the drain region  26  (the number of each region is one). In this manner, one cell is sufficient for the J-FET  20 , and the input capacitance Cin according to the decrease in the cell size can be minimized. 
     In contrast, the bipolar transistor  30  has  10  or more of minimum unit cells, each configured of one pair of the base region  31  and the emitter region  32 . The current amplification factor β of the bipolar transistor  30  can be appropriately selected according to a forming condition of the emitter region  32 . By appropriately selecting the current amplification factor β, the output current can be sufficiently amplified even in a case where the J-FET  20  having the cell size minimized to reduce the input capacitance Cin is adapted. 
     Furthermore, the amplifying element  10  according to the embodiment has an advantage that an electrostatic breakdown tolerance is higher than that of an amplifying element using only a conventional J-FET. As compared with the J-FET  20  with a horizontal current path, the bipolar transistor  30  with a vertical current path has a larger area. Accordingly, when a current starts flowing through the J-FET  20  by the applied static electricity, a large current flows through the bipolar transistor  30 , and the electrostatic current is extracted. Thus, as compared with the conventional structure shown in  FIG. 11 , the electrostatic breakdown tolerance can be improved. 
     By referring to  FIGS. 4 to 9 , a manufacturing method of an amplifying element according to the embodiment will be described. 
     The First Step ( FIG. 4 ) 
     Prepared is the substrate SB in which the n− type semiconductor layer  12  (impurity concentration: for example, approximately 5E15 cm −3 ) is laminated on the high concentration n type silicon semiconductor substrate  11  (impurity concentration: for example, approximately 5E19 cm −3 ). The substrate SB constitutes one chip of a discrete semiconductor element. 
     The Second Step ( FIG. 5 ) 
     Provided is a mask (unillustrated) in which the forming region of the back gate diffusion region and the forming region of the base region are opened in the surface of the n− type semiconductor layer  12 . Thereafter, a p type impurity (for example, boron (B)) is ion-implanted and is then simultaneously diffused by a heat treatment (for example, at approximately 1100° C. for 300 minutes). As a result, the back gate diffusion region  21  and the base region  31  are formed to have an impurity concentration of, for example, approximately 1E16 cm −3 . Here, the back gate diffusion region  21  and the base region  31  are formed in the same depth. 
     The Third Step ( FIG. 6 ) 
     Provided is a new mask (unillustrated) in which the respective forming regions of the channel region, the emitter region, the collector extraction region are opened in the surface of the n− type semiconductor layer  12 . Thereafter, an n type impurity (for example, phosphorus (P)) is ion-implanted and is then simultaneously diffused by a heat treatment (for example, at approximately 1100° C. for 420 minutes). 
     As a result, the channel region  22  is formed in the surface of the back gate diffusion region  21 , while the emitter region  32  is formed in the surface of the base region  31 . In addition, the collector extraction region  33  is formed in the surface of the n− type semiconductor layer  12 . The collector extraction region  33  is provided to be spaced apart from the base region  31  (see  FIG. 2 ). The channel region  22 , the emitter region  32 , and the collector extraction region  33  have an impurity concentration of, for example, approximately 1E16 cm −3 , and are formed in the same depth. 
     The Fourth Step ( FIG. 7 ) 
     Provided is a new mask (unillustrated) in which each of the forming regions of the top gate region, the back gate contact region, and the base contact region are opened in the surface of the n− type semiconductor layer  12 . Thereafter, a p type impurity (for example, boron (B)) is ion-implanted and is then simultaneously diffused by a heat treatment (for example, at approximately 1100° C. for 30 minutes). 
     As a result, the top gate region  24  having an impurity concentration of, for example, approximately 1E19 cm −3  is formed in the surface of the channel region  22 . At the same time, the back gate contact region  23  is formed in the surface of the back gate diffusion region  21 , while the base contact region  34  is formed in the surface of the base region  31 . 
     The top gate region  24 , the back gate contact region  23 , the base contact region  34  are formed in the same depth. 
     The Fifth Step ( FIG. 8 ) 
     Provided is a new mask (unillustrated) in which the respective forming regions of the source and drain regions, the emitter contact region, and the collector extraction contact region are opened in the surface of the n− type semiconductor layer  12 . Thereafter, an n type impurity (for example, phosphorus (P)) is ion-implanted and is then simultaneously diffused by a heat treatment (for example, at approximately 1000° C. for 60 minutes). 
     As a result, the source region  25  and the drain region  26  are formed in the surface of the channel region  22 . At the same time, the emitter contact region  35  is formed in the surface of the emitter region  32 , while the collector extraction contact region  36  is formed in the surface of the collector extraction region  33 . 
     All of the source region  25 , the drain region  26 , the emitter contact region  35 , and the collector extraction contact region  36  have an impurity concentration of approximately 1E20 cm −3 , and are formed in the same depth. 
     In the J-FET  20 , one pair of the source region  25 , the drain region  26 , and the top gate region  24  are formed in a strip shape in one back gate diffusion region  21 . In the bipolar transistor  30 , the multiple emitter regions  32  (the emitter contact regions  35 ) are formed in a strip shape in one base region  31 . The ratio of the occupancy area of the J-FET  20  to the occupancy area of the bipolar transistor  30  is, for example, 1 to 10. It should be noted that the occupancy areas respectively mean here the areas of the back gate diffusion region  21  and the base region  31 . 
     Note that, the order of the fourth step ( FIG. 7 ) and the fifth step ( FIG. 8 ) can be interchanged. 
     In addition, in the fourth and fifth steps, provided is a mask in which the respective forming regions of the top gate region, the back gate contact region, and the base contact region are opened in the surface of the n− type semiconductor layer  12 . Thereafter, a p type impurity is ion implanted. After that, provided anew is a mask in which the respective forming regions of the source region, the drain region, the emitter contact region, and the collector extraction contact region are opened. Thereafter, an n type impurity is ion implanted. After that, the p type impurity and the n type impurity are simultaneously diffused by a heat treatment. In this manner, the top gate region  24 , the back gate contact region  23 , the base contact region  34 , the source region  25 , the drain region  26 , the emitter contact region  35 , and the collector extraction contact region  36  can be simultaneously formed. 
     The Sixth and Seventh Steps ( FIG. 9 ) 
     Insulating film  13  is provided on the n− type semiconductor layer  12  and desired positions therein are opened. For example, the first electrode layer  40 , the second electrode layer  50 , the first wiring layer  60 , and the second wiring layer  70  are formed of, for example, aluminum (Al). 
     The first electrode layer  40  forms the back gate electrode  41  and the top gate electrode  42 , which are respectively connected to the back gate contact region  23  and the top gate region  24 . In addition, the first electrode layer  40  forms the gate pad electrode  43  (see  FIG. 3 ) outside the back gate diffusion region  21  of J-FET  20 . 
     The second electrode layer  50  forms the emitter electrode  51  to be connected to the emitter contact region  35 , and forms the emitter pad electrode  52  (see  FIG. 3 ) outside the base region  31  of the bipolar transistor  30 . 
     One end of the first wiring layer  60  becomes the drain electrode  61  while the other end thereof becomes the collector wiring  62 , which are respectively connected to the drain region  26  and the collector extraction contact region  36 . 
     The second wiring layer  70  forms the source electrode  71  and the base electrode  72 , which are respectively connected to the source region  25  and the base contact region  34 . 
     As a result, the source region  25  and the base region  31  are electrically connected to each other, while the drain region  26  and the collector extraction region  33  are electrically connected to each other. 
     The back surface collector electrode  80  is formed by metal deposition or the like on the back surface of the n+ type semiconductor substrate  11 . 
     The collector extraction region  33  is preferable when connected to the n type semiconductor substrate  11 . However, this increases the number of the manufacturing steps. 
     As described above, the description has been given of the case where an n channel type J-FET  20  and a npn bipolar transistor are integrated on an n type semiconductor substrate SB. However, the preferred embodiment of the present invention can be equally implemented even when the conductive type is reversed. 
       FIG. 10  is a circuit diagram of an amplifying element  10 ′ in a case where a p channel type J-FET  20 ′ and a pnp bipolar transistor  30 ′ are integrated on a p type semiconductor substrate. 
     According to the present invention, an ECM amplifying element with high input impedance and low output impedance can be firstly achieved by a one chip discrete element in which the drain region of the J-FET is connected to the collector region of the bipolar transistor. 
     The amplifying element according to the present invention is configured by integrating the J-FET on the n type semiconductor substrate serving as the collector region of the bipolar transistor. The amplifying element has the configuration in which the source region of the J-FET is connected to the base region of the bipolar transistor, while the drain region of the J-FET is connected to the collector region of the bipolar transistor. Accordingly, a voltage output from the ECM is input to the gate of the J-FET with high impedance. This voltage change controls the current flowing through the J-FET. The current flowing through the J-FET is input to the bipolar transistor, and is output after the current (voltage) is amplified. 
     In other words, since the output of the J-FET can be amplified by the bipolar transistor, a sufficient output can be obtained even when the area (cell size) of the J-FET is decreased. For example, the J-FET may be one cell, and the input capacitance Cin can be made extremely small by reducing the cell size. 
     Accordingly, the required gain can be secured by the amplification factor of the bipolar transistor. Thus, the amplifying element with less input loss and high gain can be provided. 
     Secondly, the present invention can provide an amplifying element that is a one chip discrete element in which the J-FET is formed on a substrate serving as the collector region of the bipolar transistor, and that is inexpensive and simpler as compared with an amplifier integrated circuit element using BIP-LSI, C-MOS-LSI, or Bi-C-MOS-LSI. 
     Thirdly, the amplification factor of the amplifying element can be appropriately selected according to the amplification factor of the bipolar transistor. 
     The manufacturing method according to the present invention can integrate the bipolar transistor on the same substrate by adding only one step to the manufacturing steps of the J-FET, and thus can provide an inexpensive method of manufacturing an amplifying element. 
     Furthermore, the amplifying element according to the preferred embodiment of the invention has an advantage that electrostatic breakdown tolerance is higher than that of the amplifying element using only the conventional J-FET. If the area of the bipolar transistor is larger than that of the J-FET and when a current starts flowing through the J-FET by the applied electrostatic electricity, a large current flows through the bipolar transistor and the electrostatic current is extracted. Accordingly, the electrostatic breakdown tolerance can be improved as compared with the case having the conventional configuration.