Patent Publication Number: US-2007105283-A1

Title: Manufacturing method of semiconductor device and semiconductor device

Description:
CROSS-REFERENCE TO RELATED APPLICATION  
      The present application claims priority from Japanese patent application No. 2003-367435 filed on Oct. 28, 2003, the content of which is hereby incorporated by reference into this application.  
     BACKGROUND OF THE INVENTION  
      The present invention relates to a method of manufacturing a semiconductor device such as a hybrid integrated circuit device (hybrid IC) and a semiconductor manufacturing apparatus, and to, for example, a technique effective if applied to the manufacture of a semiconductor device built in a cellular phone.  
      As one manufacturing method of a semiconductor device such as a hybrid integrated circuit device, there is known, for example, a technique for mounting a bare chip and other parts over unit sections of a package base substrate, which can be taken or picked up in multi form, thereafter sealing the bare chip and other parts with an insulating resin to form a sealing resin and then cutting the package base substrate together with the resin to thereby manufacture semiconductor devices based on the unit sections (see, for example, a patent document 1 (Japanese Unexamined Patent Publication No. Hei 11(1999)-31704)).  
      The patent document 1 has pointed out that a problem arises in that when the sealing resin is formed by a potting method, the surface of the sealing resin is hard to be flattened, and when a semiconductor device manufactured as a result thereof is surface-mounted to a circuit substrate, sorbability based on a vacuum adsorption nozzle is degraded.  
      On the other hand, there is known a semiconductor device having a structure wherein a semiconductor chip and chip parts are mounted over one surface of a module substrate and covered with an insulating resin to form a sealing or encapsulating section. When, in this case, a semiconductor device in which chip parts are fixed to a module substrate by solder connections and an encapsulating section is formed of a high elastic resin, is connected to a mounting board by solder reflow, solder of the solder-connected portion in the encapsulating section is remelted so that a malfunction such as a short occurs. The short occurs due to the fact that, for example, when solder is remelted, expanded pressure produced due to its melting peels or strips an interface between each chip part and a resin for forming the encapsulating section or an interface between the resin and the module substrate, and solder flows into it so that electrode terminals at both ends of the chip part are connected by solder. Therefore, there has been proposed a semiconductor device wherein in place of the high elastic resin, a resin (e.g., resin having an elastic modulus of 200 MPa or less at a temperature of 150° C. or more: e.g., silicone resin) having low elastic modulus is used to form an encapsulating section. The semiconductor device is capable of preventing a short because even if solder in the encapsulating section is remelted upon mounting reflow, pressure produced due to its melting expansion is relaxed by the low elastic resin (see, for example, a patent document 2 (Japanese Unexamined Patent Publication No. 2000-208668)).  
      Also the patent document 2 has described that a resin is applied onto the full surface of a multi-pickup substrate by a printing method and cured by baking to form a batch encapsulating section, and thereafter the multi-pickup substrate is subjected to primary division inclusive of the batch encapsulating section to manufacture semiconductor devices. As the resin, a silicone resin or a low elastic epoxy resin is used. As to the division, a one-row division (primary division) and fractionalization (secondary division) are performed twice, whereby a module (semiconductor device) is manufactured.  
      The patent document 2 has described that when a soft silicone resin is used upon division, the division is not perfectly done and hence a non-divided spot occurs, and the division is carried out by laser or dicing.  
      On the other hand, a semiconductor device such as a high frequency power amplifier device employed in a transmitting unit is known as a semiconductor device mounted over a mounting board of a cellular phone. The present semiconductor device has a structure wherein, for example, an electronic part comprising active parts (active elements) such as a transistor, etc. and passive parts (passive elements) such as a resistor, a capacitor, etc. is mounted over the upper surface of a module substrate having a wiring board structure. A plurality of electrode terminals (external electrode terminals) are provided over the back surface of the module substrate, and hence the present semiconductor device results in a surface-mounting semiconductor device. The module substrate is formed of a low temperature calcined substrate (low temperature calcined multilayer wiring board) formed of ceramic (see, for example, a patent document 3 (Japanese Unexamined Patent Publication No. Hei 9(1997)-116091)).  
     SUMMARY OF THE INVENTION  
      The semiconductor device built in a cellular phone is used in a high frequency region. In a semiconductor device (hybrid integrated circuit device) including a filter high frequency circuit, a filter wiring is formed in a substrate by calcination upon its manufacture. In this case, a material low in impedance such as copper (Cu), silver (Ag) is used to form the filter wiring. Since Cu and Ag are low in melting point, there is a need to fabricate the substrate by low temperature calcination. Thus, the substrate makes use of a low temperature calcined substrate (low temperature calcined multilayered wiring board).  
      In the hybrid integrated circuit device, passive elements such as a chip resistor, a chip capacitor or the like are mounted over wirings (lands) of the module substrate by solder connections. This solder is remelted upon connecting a semiconductor device to a mounting board by reflow (temporary heat treatment), thus leading to such a short as described above. Thus, in order to prevent the short caused by solder remelted within the encapsulating body, the present applicant uses such a silicone resin or low elastic epoxy resin as described in the patent document 2 as a resin for forming the encapsulating body. Then, the multi-pickup substrate (wiring board) is divided together with the resin layer for forming the encapsulating body (one-row division based on the primary division, and fractionalization by secondary division) to thereby fabricate a semiconductor device.  
      In this case, the division is done using small grooves (division lines) for division, which are defined in the lower surface of the wiring board. As described even in the patent document 2, however, when a resin layer provided over the full surface of a wiring board  150  is formed of a silicone resin layer  151  as shown in  FIG. 34 , a non-divided resin portion  152  occurs.  
      An object of the present invention is to provide a method of manufacturing a semiconductor device using a silicone resin or a low elastic epoxy resin as an encapsulating material, which is capable of reliably performing division in such a manner that a non-divided resin portion does not remain, and a semiconductor manufacturing apparatus.  
      Another object of the present invention is to provide a method of manufacturing a semiconductor device in which an encapsulating body that covers the full surface of a wiring board is formed by printing a silicone resin or a low elastic epoxy resin, which method is capable of checking whether the flatness of the surface of the encapsulating body is good or bad, and a semiconductor manufacturing apparatus.  
      The above, other objects and novel features of the present invention will become apparent from the description of the present specification and the accompanying drawings.  
      Summaries of the representative ones of the inventions disclosed in the present application will be explained in brief as follows:  
      (1) A method of manufacturing a semiconductor device, according to the present invention comprises the steps of:  
      (a) preparing a wiring board having device mounting sections and conductor layers in a plurality of areas of a first surface and having external electrode terminals in a second surface opposite to the first surface, and wherein the respective areas are brought into fractionization by division at a final manufacturing stage;  
      (b) mounting electronic parts in the plurality of areas inclusive of solder connections;  
      (c) covering the plurality of areas with an insulating resin to form a resin layer;  
      (d) preparing a division mechanism having a base (conveying chute), a first device part (support body) which faces an upper surface of the conveying chute with a predetermined interval interposed therebetween, and a second device part (clamper) disposed in such a manner that an upper clamp claw and a lower clamp claw are respectively located on the upper and lower surface sides of a protruded wiring board portion of the wiring board placed over the conveying chute such that part thereof protrudes to the division position side out of one edge of the conveying chute;  
      (e) setting the wiring board to the upper surface of the conveying chute in such a manner that a divided portion of the wiring board coincides with the division position;  
      (f) as a first dividing step, rotating the clamper relative to the support body to swing the protruded wiring board portion in an upward direction, thereby dividing the wiring board at a point where it contacts a fulcrum provided in the support body; and  
      (g) as a second dividing step, rotating the clamper in the direction opposite to the direction of rotation in said step (f) to swing the protruded wiring board portion downward and pressing the wiring board against the conveying chute to divide the wiring board again at a point divided by the first dividing step,  
      wherein the wiring board forms strip bodies in each of which the areas are arranged in a row, according to a primary dividing process based on the steps (e) through (g), and  
      wherein thereafter the strip body is divided every areas according to a secondary dividing process based on the steps (e) through (g) to thereby manufacture semiconductor devices.  
      The resin layer is formed by printing a resin (silicone resin) having an elastic modulus of 200 MPa or less at a temperature of 150° C. or more onto the wiring board and effecting defoaming processing and curing processing thereon. In the step (f), the clamper placed in an origin position in a state of pinching the protruded wiring board portion of the wiring board placed over the upper surface of the conveying chute from above and below in a non-contact state, is rotated by about 80° to 120° around the fulcrum in the upward direction. In the next step (g), the clamper is rotated in the direction opposite to the direction of rotation in the step (f) by an angle obtained by adding a rotational angle ranging from 10° to 45° to the rotational angle in the step (f).  
      A semiconductor manufacturing apparatus has such a configuration as to have a predetermined space between the lower surface of the support body and the surface of the resin layer of the wiring board placed over the conveying chute. In the clamper placed in such an origin position that the upper clamp claw and the lower clamp claw are positioned on the upper and lower surface sides of the protruded wiring board portion of the wiring board in a set state, which is placed over the conveying chute and protrudes from one edge of the conveying chute, the upper clamp claw and the lower clamp claw are positioned with a predetermined gap defined between the protruded wiring board portion and each of the upper clamp claw and lower clamp claw. In the step (f), when the clamper is rotated in the upward direction relative to the support body, the protruded wiring board portion is forced up by the lower clamp claw of the clamper in a state in which the upper clamper claw is not brought into contact with the protruded wiring board portion, thereby dividing the wiring board. In the step (g), when the clamper is rotated in the downward direction with respect to the support body, the protruded wiring board substrate portion is forced up by the upper clamp claw of the clamper in a state in which the upper clamp claw is not brought into contact with the protruded wiring board portion to thereby divide the wiring board perfectly.  
      The following semiconductor-manufacturing apparatus is used in such a manufacturing method of the semiconductor device. The semiconductor manufacturing apparatus divides a wiring board which has electronic parts respectively mounted in plural areas of a first surface and has external electrode terminals in a second surface corresponding to each of the areas and corresponding to a surface opposite to the first surface, and in which the plurality of areas are covered with an insulating resin layer, according to primary dividing processing on the basis of control of a control system to form a strip body in which the areas are arranged in a row, and thereafter divides the strip body every areas according to secondary dividing processing to thereby manufacture semiconductor devices. A one-row division mechanism for performing the primary dividing process and an individual division mechanism for performing the secondary diving processing respectively have a conveying chute which places the wiring board over its upper surface such that the resin layer assumes an upper surface, a support body which faces the upper surface of the conveying chute and faces the resin layer of the wiring board placed over the conveying chute, and a clamper which is disposed in such a manner that an upper clamp claw and a lower clamp claw are respectively disposed on the upper and lower surface sides of a protruded wiring board portion of the wiring board placed over the conveying chute in such a way that part thereof protrudes to the division position side out of one edge of the conveying chute, and are rotatably controlled in upward and downward direction respectively. In the primary dividing processing and the secondary dividing processing, the wiring board is placed over and set to the upper surface of the conveying chute such that each divided portion of the wiring board coincides with the division position. Further, the protruded wiring board portion that protrudes from the conveying chute is placed between the upper clamp claw and the lower clamp claw. Next, the clamper is rotated in the upward direction with respect to the support body to swing the protruded wiring board portion in the upward direction to allow it to contact a fulcrum provided in the support body, thereby perform a first division for dividing the wiring board. The clamper is rotated in the direction opposite to the direction of rotation in the first division to swing the protruded wiring board portion below the upper surface of the conveying chute, thereby performing a second division for dividing the wiring board at the corresponding point divided by the first division.  
      The origin position where the work of the clamper of the division mechanism is started, corresponds to a position where in a state in which the wiring board is set to the upper surface of the conveying chute, the upper clamp claw and the lower clamp claw are located above and below the protruded wiring board portion in a non-contact state and kept in its nipped state. The clamper is configured so as to be capable of being rotated by at least 80° to 120° from the origin position about the fulcrum in the upper direction and being rotated in the forward and reverse directions over at least about 10 to 45 degrees in the downward direction.  
      Also the semiconductor manufacturing mechanism includes a control system that controls the entirety, a loader which supplies the wiring board to the one-row division mechanism, a conveying mechanism which conveys the strip body divided and formed by the one-row division mechanism in its longitudinal direction and supplies it to the individual division mechanism, an individual conveying mechanism which sequentially and individually conveys semiconductor devices divided and fractionalized by the individual division mechanism to one to plural stages, and a pickup mechanism which holds the semiconductor device at the final stage by a tool under vacuum adsorption, conveys each non-defective product to a non-defective storage unit under the control of the control system, and conveys each defective product to a defective product storage unit.  
      The pickup mechanism has a tool which adsorbs under vacuum a semiconductor device onto a lower end surface, a drive unit which holds the tool and three-dimensionally moves and controls the tool, a vacuum source connected to the tool via a tubing or pipe arrangement, a solenoid-operated valve which is connected to the tubing in a communicating state and performs an on/off operation by the control system, and a digital vacuum meter which is connected between the solenoid-operated valve and the tool and measures the degree of vacuum in the tool. Information about the degree of vacuum measured by the digital vacuum meter is transmitted to the control system. The control system controls the pickup mechanism based on the information about the degree of vacuum. When the degree of vacuum is greater than or equal to the reference degree of vacuum, the control system conveys each semiconductor device to the non-defective storage unit. When the degree of vacuum is less than the reference degree of vacuum, the control system conveys each semiconductor device to the defective product storage unit.  
      Advantageous effects obtained by representative ones of the inventions disclosed in the present application will be explained in brief as follows:  
      (1) A resin layer formed by printing of a silicone resin is subjected to defoaming processing and curing processing (bake processing) after its printing. A heavy substance such as a filler contained in a resin at the defoaming processing long in processing time sinks from the upper surface side to the wiring board side at its lower surface. As a result, the surface of the resin layer is brought to a layer of a resin component hard to tear off. Thus, a compression force merely acts on the layer of the resin component in the surface layer of the resin layer even if the wiring board is divided, in the case of such a division that the wiring board is folded back to the resin layer side. Therefore, the resin portion remains without the division of the wiring board (non-divided resin portion remains). In the dividing method according to the present invention, a wiring board formed of ceramic is forced up (upper swing) by means of a lower clamp claw of a clamper, and some of a protruded wiring board portion that protrudes from a conveying chute is pressed against a support body to carry out a first division under bending stress. Thereafter, the upward-located clamper is rotatably swung (lower swing) downward to allow an upper clamp claw to press down the protruded wiring board portion, thereby performing a reverse division at the first division section again as a second division. Since the second division allows a tensile force to act on a remaining and thin non-divided resin portion, the non-divided resin portion is torn off. Thus, the perfect division is enabled. Fractionalizing is done by a one-row division and an individual division so that each semiconductor device is manufactured.  
      (2) A pickup mechanism, which conveys products brought to semiconductor devices by being fractionized, vacuum-adsorbs and holds a semiconductor device at a final stage by a tool but measures the degree of vacuum in its held state. Then, the pickup mechanism is controlled based on information about the degree of vacuum. When the measured degree of vacuum is greater than or equal to the reference degree of vacuum, the pickup mechanism conveys the semiconductor devices to the corresponding non-defective product storage unit. When the degree of vacuum is less than the reference degree of vacuum, the pickup mechanism conveys the semiconductor devices to the corresponding defective product storage unit. Thus, only products in each of which the flatness of the surface of an encapsulating body is satisfactory, can be shipmented. As a result, the pickup of each semiconductor device is done reliably upon the work of mounting of the semiconductor device by a user, thus making it possible to carry out satisfactory mounting. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS  
      FIGS.  1 ( a ) to  1 ( c ) are typical views showing a method of manufacturing a semiconductor device, according to a first embodiment of the present invention;  
       FIG. 2  is a perspective view illustrating an external appearance of a semiconductor device manufactured by the semiconductor device manufacturing method according to the first embodiment of the present invention;  
       FIG. 3  is a typical enlarged cross-sectional view of the semiconductor device;  
       FIG. 4  is a typical enlarged bottom-view of the semiconductor device;  
       FIG. 5  is a block diagram showing a circuit configuration of part of a cellular phone with the semiconductor device built therein;  
       FIG. 6  is a flowchart for describing the method of manufacturing the semiconductor device, according to the first embodiment of the present invention;  
      FIGS.  7 ( a ) to  7 ( c ) are cross-sectional views for describing respective steps showing the method of manufacturing the semiconductor device;  
       FIG. 8  is a flowchart showing a substrate dividing method at the manufacture of the semiconductor device;  
       FIG. 9  is a perspective view showing an external appearance of a semiconductor manufacturing apparatus employed in the manufacture of the semiconductor device according to the first embodiment of the present invention;  
       FIG. 10  is a typical plan view illustrating working stages and their related mechanisms of the semiconductor manufacturing apparatus;  
       FIG. 11  is a typical plan view showing part of a one-row division mechanism of the semiconductor manufacturing apparatus;  
       FIG. 12  is a typical cross-sectional view taken along line A-A of  FIG. 11 ;  
      FIGS.  13 ( a ) to  13 ( d ) are typical views showing respective operation stages of the one-row division mechanism;  
       FIG. 14  is a typical view depicting substrate division illustrative of a modification of the first embodiment;  
       FIG. 15  is a typical plan view showing an individual dividing mechanism for individually dividing a substrate, of the semiconductor manufacturing apparatus;  
       FIG. 16  is a typical cross-sectional view taken along line B-B of  FIG. 15 ;  
       FIG. 17  is a typical plan view depicting a slide manner for eliminating a defective product in the individual dividing mechanism;  
       FIG. 18  is a typical cross-sectional view taken along line C-C of  FIG. 17 ;  
       FIG. 19  is a graph showing a correlation between upper swing angles at one-row division with respect to a silicone resin and the remaining amount of resin (thickness of non-divided resin portion) that covers the substrate;  
       FIG. 20  is a graph illustrating a correlation between substrate division positions at the individual division and cutting angles (lower swing angles) at their positions;  
       FIG. 21  is a graph showing a correlation between upper swing angles at one-row division with respect to a low elastic epoxy resin and the remaining amount of resin (thickness of non-divided resin portion) that covers the substrate;  
      FIGS.  22 ( a ) to  22 ( d ) are typical views illustrating respective operation stages of the individual dividing mechanism;  
       FIG. 23  is a typical side view schematically showing a thickness inspection mechanism of a thickness inspection stage of the semiconductor manufacturing apparatus;  
       FIG. 24  is a typical side view schematically showing a positioning mechanism of a positioning stage of the semiconductor manufacturing mechanism;  
       FIG. 25  is a typical side view illustrating a size inspection mechanism of a size inspection stage of the semiconductor manufacturing apparatus;  
      FIGS.  26 ( a ) to  26 ( c ) are typical views showing the operation of the size inspection mechanism;  
       FIG. 27  is a typical view schematically showing a pickup mechanism for detecting whether planarization of each of products is good or bad, which is employed in the semiconductor manufacturing apparatus;  
      FIGS.  28 ( a ) and  28 ( b ) are typical views showing a vacuum suction state of a product judged as a non-defective product by the pickup mechanism and the state of flatness of a pre-division substrate covered with a resin layer;  
      FIGS.  29 ( a ) and  29 ( b ) are typical views showing a vacuum suction state of a product judged as a defective product by the pickup mechanism and the state of flatness of a pre-division substrate covered with a resin layer;  
      FIGS.  30 ( a ) and  30 ( b ) are typical views illustrating a dividing mechanism employed in a semiconductor manufacturing apparatus showing a second embodiment of the present invention and a state of division by the dividing mechanism;  
       FIG. 31  is a typical view showing a state in which a division position of a substrate cannot be determined;  
       FIG. 32  is a typical view showing a state of division by a dividing mechanism illustrative of a modification of the second embodiment of the present invention;  
      FIGS.  33 ( a ) to  33 ( c ) are typical views showing a state of division of a strip body at each substrate position; and  
       FIG. 34  is a typical view illustrating a divided state of a substrate covered with a conventional silicone resin.  
    
    
     DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS  
      Preferred embodiments of the present invention will hereinafter be described in detail with reference to the accompanying drawings. Incidentally, elements each having the same function are given like reference numerals through all the drawings for describing the embodiments of the invention, and their repetitive description will be omitted.  
     First Preferred Embodiment  
      The first embodiment will explain an example in which the present invention is applied to the manufacture of a semiconductor device (hybrid integrated circuit device) built in a cellular phone.  FIGS. 1 through 29  are drawings related to a method of manufacturing a semiconductor device, showing the first embodiment of the present invention, and a semiconductor manufacturing apparatus.  FIGS. 2 through 7  are drawings related to the semiconductor device manufactured by the first embodiment. FIGS.  1 ( a ) to  1 ( c ) and  FIGS. 8 through 29  are drawings related to the semiconductor manufacturing apparatus.  
      As shown in  FIG. 2 , the semiconductor device (hybrid integrated circuit device)  1  manufactured by the semiconductor device manufacturing method according to the present embodiment comprises, in appearance, a module substrate  2  constituted of a square-shaped low temperature calcined laminated substrate, and an encapsulator or encapsulating body  3  formed of an insulating resin that covers the upper surface of the module substrate  2 .  
      A low elastic resin is used as the resin for forming the encapsulating body  3 . As the low elastic resin, a resin having an elastic modulus of 200 MPa or less at a temperature of 150° C. or more, or a resin having an elastic modulus of over 1 MPa to under 200 MPa at the temperature of 150° C. or more and an elastic modulus of over 200 MPa at a temperature of 25° C. is used. A silicone resin is known as the resin having the elastic modulus of 200 MPa or less at the temperature of 150° C. or more. An epoxy resin is known as the resin having the elastic modulus of over 1 MPa to under 200 MPa at the temperature of 150° C. or more and the elastic modulus of over 200 MPa at the temperature of 25° C. In the present embodiment, the encapsulating body  3  is formed of the silicone resin.  
      As shown in  FIG. 3 , a plurality of external electrode terminals  4  are provided over the back surface of the encapsulating body  3 .  FIG. 4  is a view showing the back surface of the semiconductor device  1 . Large and small square portions respectively correspond to the external electrode terminals  4 . The edges of the external electrode terminals  4  are covered with an insulating film  5  comprising an alumina coat film provided over the back surface of the encapsulating body  3 . And portions uncovered with the insulating film  5  serve as substantial external electrode terminal portions that contribute to connections. In  FIG. 4 , the external electrode terminals  4  lying in an area surrounded by a dotted lie frame correspond to ground electrodes respectively.  
      The thickness of the semiconductor device  1  is about 1.6 mm, and the thickness of the module substrate  2  is about 0.75 mm, for example. The module substrate  2  is a low temperature calcined substrate (low temperature calcined alumina ceramic substrate) and corresponds to a substrate having a laminated structure as shown in  FIG. 3 . Conductor layers  7   a ,  7   b  and  7   c  are respectively provided in the upper surface, middle layer and lower surface of the module substrate  2 . Conductors  7   d , which extend through the respective layers of the module substrate  2  and electrically connect any of the conductor layers  7   a ,  7   b  and  7   c , are provided. Further, recesses  8  are defined in the upper surface of the module substrate  2  at predetermined spots. A device mounting conductor layer  7   e  is provided even at the bottom of each of these recesses  8 . A semiconductor chip (active part: active element)  9  is fixed (mounted) onto its corresponding conductor layer  7   e  through an unillustrated adhesive interposed therebetween. Electrodes placed over the upper surface of each semiconductor chip  9  and the predetermined conductor layers  7   a  placed in the upper surface of the module substrate  2  are respectively electrically connected to one another by conductive wires  10 . Respective pairs of conductor layers  7   a  are provided in the upper surface of the module substrate  2 . Electrode portions of chip type electronic parts  11 , are electrically connected via solder  12  to these pairs of conductor layers  7   a  respectively. The chip type electronic parts  11  are passive parts (passive elements) such as a chip resistor, a chip capacitor, a chip inductor, etc. Circuit elements such as the active elements, passive layers, etc. are mounted over a first surface of the module substrate  2  as described above.  
      On the other hand, the insulating film  5  is selectively formed in the lower surface of the module substrate  2 . The insulating film  5  partly cover the respective conductor layers  7   c . Square-shaped external electrode terminals, which form power supply terminals, signal terminals, etc., are arranged in a row along the edges of the module substrate  2  although they are discontinuous in mid course.  
      As shown in  FIG. 4 , a plurality of ground electrodes  4   f , which also serve as external electrode terminals, are provided from the interior of the module substrate  2  to, partly, its each edge. The ground electrodes  4   f  are equivalent to ones obtained by exposing, in subsection form, the conductor layers  7   c  formed in the lower surface of the module substrate  2  over a wide area by the insulating film  5 . A plating film  15  is formed over the surface of each of the external electrode terminals  4  exposed from the insulating film  5  (see  FIG. 3 ). Although not shown in the figure, the plating film  15  comprises a first plating film corresponding to a lower layer and a second plating film formed over the first plating film. For example, the conductor layer  7   c  is equivalent to one formed by printing paste containing Pt over Ag and calcining it. The first plating film is Au and the second plating film is Ni. This structure is similar even to the ground electrodes  4   f.    
      Described specifically, the semiconductor device  1  according to the present embodiment is a hybrid integrated circuit device  1  containing a power amplifier device (high frequency power amplifier device), a duplexer, etc., which is operated at an operating frequency of 800 MHz or higher. Thus, a description will be made of a cellular phone (wireless communication device) incorporating the semiconductor device  1  (high frequency power amplifier device) according to the present embodiment therein.  FIG. 5  is a block diagram showing part of a dualband wireless communication device. This is a block diagram showing a high frequency power amplifier device having an amplification system for a GSM system and an amplification system for a DCS system in a wireless communication system, and part of a cellular phone of a dualband system capable of these two communication systems.  
      The block diagram of  FIG. 5  shows a part or section from a high frequency signal processing IC (PF linear)  20  to an antenna  39 . As shown in the same figure, a GSM signal sent from the high frequency signal processing IC  20  is transmitted to an amplifier (PA)  21  for GSM, and the output of the amplifier  21  is detected by a coupler  22 . The signal detected by the coupler  22  is fed back to an automatic power control circuit (APC circuit)  23 . The APC circuit  23  is operated based on the detected signal to control the amplifier  21 . Similarly, a DCS signal sent from the high frequency signal processing IC  20  is transmitted to an amplifier (PA)  24  for DCS. The output of the amplifier  24  is detected by a coupler  25 . The signal detected by the coupler  25  is fed back to the APC circuit  23 . The APC circuit  23  is operated based on the detected signal to control the amplifier  24 .  
      The output of the amplifier  21  is transmitted to a filter  26  through an output terminal Pout 1  and inputted to a duplexer  38  through a transmit-receive changeover switch  27 . The antenna  39  is connected to an output terminal of the duplexer  38 . Similarly, the output of the amplifier  24  is transmitted to a filter  35  through an output terminal Pout 2  and inputted to the duplexer  38  through a transmit-receive changeover switch  36 .  
      The transmit-receive changeover switches  27  and  36  are changed over in response to control signals sent from control terminals cont 1  and cont 2  to send out a signal received by the antenna  39  to receiving terminals RX 1  and RX 2 . These signals are transmitted to the high frequency signal processing IC  20  through the filters  30  and  37  and low noise amplifiers (LNAs)  31  and  38 . The wireless communication device enables GSM and DCS communications.  
      As shown in  FIG. 5 , the semiconductor device  1  according to the present embodiment has a structure wherein the amplifiers (PAs)  21  and  24 , the couplers  22  and  25 , the filters  26  and  35 , the transmit-receive changeover switches  27  and  36  and the duplexer  38  are formed integrally.  
      As shown in  FIG. 6 , such a semiconductor device  1  is manufactured via process steps for preparing a substrate (S 1 ), mounting electronic parts (S 2 ), forming a resin layer (S 3 ) and performing division (S 4 ). FIGS.  7 ( a ) through  7 ( c ) are respectively typical cross-sectional views showing the state of the substrate in the respective steps. A substrate  2   a  comprising a low temperature calcination ceramic wiring board for forming the module substrate  2  shown in the description of the structure of the semiconductor device  1  is prepared (S 1 ).  
      The substrate  2   a  is configured as a pattern in which square-shaped areas (product forming sections) for manufacturing one semiconductor device are arranged in line in matrix form. FIGS.  7 ( a ) to  7 ( c ) show part of the substrate  2   a , i.e., a single or unitary area (product forming section)  2   c . A module substrate is formed by dividing and fractionalizing the unitary area. Since a wiring structure of the unitary area  2   c  corresponds to the already-described structure of module substrate, it will be omitted.  
      As shown in  FIG. 7 ( a ), recesses  8  are defined in a first surface of each area (product forming section)  2   c . A conductor layer  7   e  is provided at the bottom of each recess  8 . Conductor layers  7   a  for connecting electrodes at both ends of each chip type electronic part and wires are formed over the first surface. External electrode terminals  4  are provided at predetermined spots of the opposite surface, i.e., second surface of each area  2   c  of the substrate  2   a . Areas other than the external electrode terminals  4  are covered with an insulating film  5 .  
      Thus, as shown in  FIG. 7 ( b ), the mounting of the electronic parts is performed. That is, a semiconductor chip  9  is fixed onto its corresponding conductor layer  7   e  at the bottom of each recess  8 . Further, respective electrodes provided over the upper surface of each semiconductor chip  9  and its peripheral conductor layers  7   a  are connected by conductive wires  10 . Also electrode portions at both ends of each chip type electronic part  11  are connected to the pair of conductive layers  7   a  by solder  12 . The mounting of the electronic parts (S 2 ) is contained in the mounting of the semiconductor chips  9  and the mounting of the chip type electronic parts  11  and also includes electrical connections among the conductor layers  7   a  and  7   e  of the substrate  2   a , the semiconductor chips  9  and the chip type electronic parts  11 .  
      Next, as shown in  FIG. 7 ( c ), a resin layer  3   a  is formed over a first surface of the substrate  2   a  (S 3 ). The resin layer  3   a  is formed by printing a resin having an elastic modulus of 200 MPa or less at a temperature of 150° C. or higher to a predetermined thickness (e.g., thickness ranging from 0.75 mm to 0.8 mm), effecting defoaming processing on it and performing its curing processing (bake processing). Described specifically, a silicone resin is printed. After its printing, bubbles contained in the resin layer are defoamed (deaerated). This defoaming processing is performed by leaving the substrate  2   a  under a vacuum atmosphere (53 hpa) for about 10 to 20 minutes. The bake processing is carried out by leaving the substrate  2   a  under an atmosphere at 150° C. for 90 minutes.  
      The silicone resin is used to prevent a short with remelting of solder in an encapsulating body upon mounting of the semiconductor device on a mounting board by reflow. To this end, a resin having an elastic modulus of over 1 MPa to under 200 MPa at a temperature of 150° C. or more and an elastic modulus of over 200 HPa at a temperature of 25° C. can also be used. A low elastic epoxy resin is used as the resin.  
      Next, a fail mark is applied onto an exposed surface of the substrate  2   a  formed with the resin layer  3   a , i.e., a second surface thereof with respect to a defective product by an inkjet method or the like. The fail mark is detected in a subsequent process and a product with the fail mark applied thereon is eliminated. The fail mark is applied onto the same position as the second surface of the substrate  2   a  by the ink jet method or the like after detection of a fail mark (fail mark applied for a substrate initial failure and an assembly failure in advance) applied onto the upper surface of the substrate by recognition before printing in S 3  of  FIG. 6 .  
      Next, the substrate  2   a  is divided (S 4 ) together with the resin layer  3   a  to form such a semiconductor device  1  as shown in  FIG. 3 . This division is performed according to a primary dividing process and a secondary dividing process. The primary dividing process is of a one-row dividing process and corresponds to such division of the substrate  2   a  as to form a strip body in which areas thereof are arranged in a row. The secondary dividing process is of an individual dividing process and is equivalent to such division as to sequentially divide the strip body at the boundaries among the areas and bring it into fractionalization thereby to form the semiconductor device  1 .  
      In the present embodiment, the division at each of the primary dividing process (one-row division) and the secondary dividing process (individual division) is performed by such a semiconductor manufacturing apparatus  43  as shown in  FIG. 9 . The semiconductor manufacturing apparatus  43  has its front face and a plurality of openable/closable doors  54 . A control panel  46  is provided at its front face. Although not shown in the drawing in particular, the semiconductor manufacturing apparatus  43  is provided thereinside with a control system capable of, for example, effecting arithmetic processing on drive control of respective mechanism portions and detected information (measured information) obtained by various detections and driving and controlling respective portions, based on the information.  
      As indicated by a flowchart shown in  FIG. 8 , the semiconductor manufacturing apparatus  43  is capable of performing respective step operations such as preparation of a post-encapsulation substrate (S 11 ), one-row division (S 12 ), individual division (S 13 ), selection of a defective product (S 14 ), thickness detection (S 15 ), size detection (S 16 ), flatness detection (S 17 ), and selection of non-defective/defective product (S 18 ).  
       FIG. 10  is a typical plan view showing respective working stages and their related mechanisms of the semiconductor manufacturing apparatus. In  FIG. 10 , a one-row dividing stage A, a fail mark detecting stage B, an individual division stage C, a thickness detecting stage D, a positioning stage E, a size detecting stage F, a non-defective product holding stage G and a defective product holding stage H are disposed. These stage portions are respectively configured of predetermined units.  
      At the one-row dividing stage A, a substrate (wiring board)  2   a  having a resin layer, in which product forming sections (areas) are disposed in matrix form, is pitch-fed sequentially and subjected to division for each row. Racks designated at numerals  51  and  51  are sequentially set to a substrate loader by manual. Substrates  2   a  placed in a stacked state, which are set to the substrate loader  50 , are sequentially fed out to the one-row dividing stage A one by one by means of a substrate supply mechanism  52 . Although not shown in the drawing, the substrate supply mechanism  52  takes a pusher configuration. The substrates  2   a  are fed out one by one by means of the pusher. Then, the substrates  2   a  are pitch-fed to the one-row dividing stage A by means of an unillustrated conveying mechanism. At the one-row dividing stage A, each substrate  2   a  is divided one row by one row so that slender strip bodies  2   g  are formed. The strip body  2   g  has a structure in which the product forming sections (areas) are arranged in a row therein.  
      In the present embodiment, the two divisions of the primary dividing process (one-row division) for forming the strip body  2   g , and the secondary dividing process (individual division) for dividing the strip body  2   g  at the boundaries among the respective areas (product forming sections) to provide fractionization thereof are performed in the case of the division of the substrate  2   a . These divisions are performed by a division mechanism of such a mechanism as shown in FIGS.  1 ( a ) and  1 ( b ). Incidentally, even if one referred to above is called simply “substrate  2   a ” in the following description, it means the substrate  2   a  having the resin layer  3   a  in the description up to the individual division.  
      The division mechanism includes a base (conveying chute)  55  which places the substrate  2   a  (wiring board) over its upper surface such that the resin layer  3   a  serves as an upper surface, and a first device part (support body)  56  which faces the upper surface of the conveying chute  55  and faces the resin layer  3   a  of the substrate  2   a  placed over the conveying chute  55 . A second device part (clamper)  59  is placed which is disposed in such a manner that an upper clamp claw  57  and a lower clamp claw  58  are positioned on the upper and lower surface sides of a protruded wiring board portion  2   j  of the substrate  2   a , which is placed over the conveying chute  55  such that part thereof protrudes toward the division position side out of one edge (right edge in this figure) of the conveying chute  55 . As shown in  FIG. 1 ( a ), the clamper  59  having such an attitude as to pinch the protruded wiring board portion  2   j  of the substrate  2   a , comprising a flat plate placed over the conveying chute  5  in a flat state from the side in a state (non-contact state) in which it is not brought into contact with the substrate  2   a  and the resin layer  3   a , is called “clamper” at the origin position. The clamper  59  at the origin position is set in such a manner that the upper clamp claw  57  and the lower clamp claw  58  are held in front of the protruded wiring board portion  2   j  with a clearance or gap ranging from about 0.2 to 0.3 mm being defined therebetween.  
      In the state in which the substrate  2   a  is being placed over the conveying chute  55 , a gap of a predetermined size is defined between the resin layer  3   a  on the upper side of the substrate  2   a  and the lower surface of the support body  56 . This aims to first bring the resin layer  3   a  placed over the upper surface of the substrate  2   a  into contact with the right edge of the support body  56  when the clamper  59  is turned upward to raise the protruded wiring board portion  2   j  with the lower clamp claw  58  and to divide the substrate  2   a  (and the resin layer  3   a ) at its contact portion. The portion where the resin layer  3   a  placed over the upper surface of the substrate  2   a  is first brought into contact with the support body  56 , i.e., the right edge is called a fulcrum or support point  56   a.    
      The lower surface of the support body  56  is made flat in such a manner that when the protruded wiring board portion  2   j  is forced up, the substrate  2   a  with the resin layer is first brought into contact with the fulcrum  56   a . The gap between the resin layer  3   a  and the lower surface of the support body  56  is also set so as to range from about 0.2 to 0.3 mm.  
      With the rotation of the clamper  59  in the upward direction, the lower clamp claw  58  forces up the protruded wiring board portion  2   j . Therefore, bending stress is exerted on the substrate  2   a  with the fulcrum  56   a  as the center so that division occurs in the substrate portion brought into contact with the fulcrum  56   a . Thus, the positions of the fulcrum and a line segment extending downward from the fulcrum are called division positions.  
      In order to facilitate the division of the substrate  2   a , grooves (division grooves)  2   p  are defined in the second surface (lower surface in  FIG. 1 ) of the substrate  2   a  as shown in  FIG. 1 ( a ). The division grooves  2   p  are provided at predetermined intervals. Although a portion (line segment) on the right end side to be first divided is indicated by a thick line in  FIG. 1 ( a ), a groove (division groove)  2   p  is provided even on the lower surface side of the substrate  2   a , which coincides with such a line segment. Each of the grooves  2   p  is formed as a groove having a V-shaped section such that the concentration of stress is easy to occur therein. In the drawings for subsequent description of division inclusive of  FIG. 1 , the division grooves  2   p  are shown only in  FIG. 1 ( a ) but they are omitted in  FIG. 1 ( b ) and subsequently.  
      A conveying claw  60  shown on the left side pitch-feeds the substrate  2   a  lying over the conveying chute  55 . The portion to be first divided is aligned with its corresponding division position upon the first dividing operation. After this setting, each division groove  2   p  is always placed in its corresponding division position by pitch-feeding.  
      The clamper  59  can be rotated in upward and downward direction, respectively, from the state being placed in the origin position. As to the rotation of the clamper  59 , the clamper  59  is configured so as to be capable of being rotated from the origin position with the fulcrum as the center to at least 80° to 120° in the upper direction and being rotated in the forward and reverse directions over at least about 10 to 45 degrees in the downward direction.  
      In such a division mechanism, as shown in  FIG. 1 ( b ), the clamper  59  placed in the origin position is rotated in the upward direction with the fulcrum  56   a  as the center to swing the protruded wiring board portion  2   j  upward and allow it to contact the fulcrum  56   a  provided at the support body  56 , thereby dividing the substrate  2   a  (first division). However, in the rotation in such a one return direction, although described later, the surface layer portion of the resin layer  3   a  over the upper surface of the substrate  2   a  is not divided even if the substrate  2   a  formed of ceramic is divided, as indicated in an enlarged form on the right side of  FIG. 1 ( b ), so that a non-divided resin portion  3   s  occurs. That is, a division section (division line)  62  results in a state of stopping in the course of the resin layer  3   a.    
      Thus, as shown in  FIG. 1 ( c ), the clamper  59  is rotated in the direction opposite to the direction of rotation at the first division to swing the protruded wiring board portion  2   j  below the upper surface of the conveying chute  55 , thereby perfectly dividing the substrate  2   a  at the spot (division section  62 ) divided by the first division (second division). In the second division, as in the case of an upper drawing indicated in an enlarged form below  FIG. 1 ( c ), the end faces of the divided substrates constituted of ceramic firstly collide with each other and hence tensile stress acts on the non-divided resin portion  3   s . As a result, the leading end of the division section (division line)  62  continues to extend to the non-divided resin portion  3   s  as indicated in an enlarged form below  FIG. 1 ( c ), whereby the non-divided resin portion  3   s  is also divided perfectly at the end. Incidentally, the turning angles or the like at the first division and the second division will be explained in the description of the one-row division mechanism.  
      The one-row division mechanism and the individual division mechanism are also basically configured such as shown in  FIG. 1 . However, the one-row division mechanism is different from the individual division mechanism in that, for example, since the former is wide in division width as compared with the latter, the conveying chute  55  and the support body  56  are made broadscale in structure, there is a need to cause the support body  56  to have rigidity since a large force is exerted on the support body  56 , and a first division angle is made large. Incidentally, portions that perform the same action will be explained using the same names and the same reference numerals in the description of the one-row division mechanism and the individual division mechanism.  
      The respective portions will next be explained along the direction of an arrangement of the stages of the semiconductor manufacturing apparatus  43 . As shown in  FIGS. 11 and 12 , the conveying chute  55  for placing each substrate  2   a  over its upper surface is disposed at the section of the one-row division stage A. A sheet of substrate  2   a  is delivered to the conveying chute  55  by the substrate loader  50 . The substrate  2   a  is pitch-fed to the right side by a conveying claw  60  in  FIGS. 11 and 12 . The conveying claw  60  is supported by a support arm  61 . The support arm  61  is attached to an unillustrated drive unit and performs pitch-feeding and a tact operation to transfer the substrate  2   a  to its corresponding division position sequentially. A support body  56  is located above the right end of the conveying chute  55 . The support body  56  comprises a lower section having a fulcrum or support point  56   a , and a plate-shaped section  65  connected to the lower section. A rod  66   b  of a vertically movable cylinder  66  is fixed to the upper end of the plate-shaped section  65  and serves so as to move the support body  56  upward and downward by the vertical movements of the rod  66   b . When the substrate  2   a  is placed over the conveying chute  55 , the support body  56  is raised.  
      The clamper  59  referred to above is disposed over the extension of the right end of the conveying chute  55 . A lower clamp claw  58  is fixed to a support block  68  rotated vertically about the center of rotation  67  (see  FIG. 11 ). Also, an upper clamp claw  57  has bot ends fixed with bolts  69 . Both ends of the support block  68  are fixed to their corresponding rotatable shafts  71   a  and  71   b , which are respectively supported by support members  70   a  and  70   b . One end of one rotatable shaft  71   a  is fixed to the support block  68 , and a driven pulley  72  is fixed to the other end thereof. Also the other rotatable shaft  71   b  is rotatably supported by the support member  70   b  via a bearing.  
      The driven pulley  72  is mounted on a drive belt  76  mounted on a drive pulley  75  fixed to a rotatable shaft  74  of a division swing motor  73 . Thus, the rotatable shaft  71  is rotated in the forward and reverse directions under forward/reverse rotational drive of the one-row division swing motor  73 . As a result, the clamper  59  is rotated vertically. As shown in  FIG. 12 , the center of rotation  67  is set to the position where it coincides with the fulcrum  56   a  of the support body  56 .  
      A description will now be made of the rotating angles of upper and lower swings of the clamper in the one-row division mechanism and the individual division mechanism.  FIGS. 19 and 20  show data obtained by experiments and analyses made by the present inventors.  FIG. 19  is a graph showing a correlation between upper swing angles at one-row division of the substrate and the remaining amount of resin (the thickness of the non-divided resin portion) that covers the substrate. When the thickness of the resin layer  3   a  is set as 800 μm, for example, the substrate  2   a  formed of ceramic is divided at about an upper swing angle of about 20° (see a point P indicated in the same graph), as is understood from the graph of  FIG. 19 . When the upper swing angle is 70°, the thickness of the non-divided resin portion (remaining amount of resin) results in about 250 μm. When the upper swing angle is 80°, the remaining amount of resin (thickness) becomes approximately 220 μm. It is understood that when the upper swing angle is made large sequentially, the remaining amount of resin becomes thin sequentially. Although most ones are perfectly divided if the upper swing angle is set to 180°, the adoption of the upper swing angle of 180° is difficult from the relationship of layouts among the respective mechanism portions.  
      Thus, checks were made, at the division of the strip body  2   g , as to when the perfect division at the second division has occurred where the upper swing angle was set to 120°.  FIG. 20  is a graph showing a correlation between substrate division positions at the substrate individual division and cutting angles (lower swing angles) at their positions.  
      The substrate  2   a  in which the areas (product forming sections) are disposed rectangularly in matrix form, has a non-used frame portion  2   s  that exists around the areas (product forming sections)  2   c  arranged in matrix form in consideration of product reliability as shown in  FIG. 10 . Thus, when the primary dividing process is done to form a strip body  2   g , a frame portion  80 , which protrudes toward the clamper  59  side upon the first division, exists in the form in which divisions are sequentially made at seven spots of numbers 0 to 6 corresponding to substrate positions as shown in  FIG. 20 . FIGS.  33 ( a ) to  33 ( c ) show the divisions (division positions  0 ,  1  and  6 ) at the respective substrate positions. Incidentally, division processing will now be explained under the configuration of  FIG. 1 .  FIG. 33 ( a ) shows a state in which the frame portion  80  is forced up by the clamper  59  and thereby divided at the division position  0 .  FIG. 33 ( b ) shows a state in which the first area (product forming section)  2   c  is swung upward at the division position  1  to achieve its division.  FIG. 33 ( c ) shows a state in which the final area (product forming section)  2   c  is swung downward to divide it from a frame portion  81  (at the division position  6 ). The frame portion  81  is placed over the conveying chute  55 . Owing to the existence of these frame portions  80  and  81  short in length, the strip body is perfectly divided at a lower swing angle of 26° downwardly from the state in which the clamper is placed in the origin position, in the case of the first division. In the case of the final division, it is perfectly divided at a lower swing angle of 28°. The angles are marked with minus (−) here since the clamper placed in the origin position is swung downward. It is understood that the strip body can be perfectly divided in a lower swing angular range of −11° to −15° in the case of the respective divisions at the substrate positions of 1 to 5. These data correspond to the case in which the resin layer  3   a  is formed of a silicone resin.  
      According to the result of other experiments made by the present inventors, it was understood that when the upper swing angle was 80° and 90° under the condition in which the length of one row was set to about 75 mm, the substrate could be divided at lower swing angles of approximately, 40° and 35° respectively.  
      From the above result of experiments, the present inventors have found out that when the upper swing angle is increased upon division of the substrate, the lower swing angle can be made small, whereas when the upper swing angle is made small in reverse, there is a need to increase the lower swing angle.  
      The first embodiment shows the example in which in the case of the first division at each of the one-row division and the individual division, the clamper  59  placed in the origin position is rotated to the upper swing angle of 90°, and in the case of the subsequent second division, the clamper  59  is rotated in the reverse direction and turned up to an angular position of 20° downwardly from the origin position. If the remaining amount of resin (thickness) is set to 0.1 mm or less at the first division here, then the substrate can be divided at a small angle and reliably upon the second division.  
      A description will now be made of a case in which the resin layer  3   a  is formed of a low elastic epoxy resin.  FIG. 21  is a graph showing a correlation between upper swing angles at the division of a substrate in which a resin layer is formed of an epoxy resin having a low elastic modulus and the remaining amount of resin (thickness of non-divided resin portion) that covers the substrate.  
      According to the result of other experiments made by the present inventors, it was understood that when the upper swing angle was 30° and 40° under the condition in which the length of one row was set to about 75 mm, the substrate could be divided at a lower swing angle of approximately, 30°.  
      From the above result of experiments, the present inventors have found out that when the upper swing angle is increased upon division of the substrate, the lower swing angle can be made small, whereas when the upper swing angle is made small in reverse, there is a need to increase the lower swing angle.  
      When the resin layer  3   a  is formed of the low elastic epoxy resin, the clamper  59  placed in the origin position is rotated up to an upper swing angle of 40′ in the first division at each of the one-row division and the individual division, and the clamper  59  is rotated in the reverse direction in the subsequent second division to turn up to an angular position of 30° downwardly from the origin position. Thus, the perfect division can be performed.  
      FIGS.  13 ( a ) through  13 ( d ) show a method of forming a strip body  2   g  by the first division and the second division at the one-row division mechanism. As shown in.  FIG. 13 ( a ), a substrate  2   a  is positioned and placed over the upper surface of the conveying chute  55 .  
      Next, as shown in  FIG. 13 ( b ), the clamper  59  is rotated by 90° (forward-rotated) upward about the fulcrum  56   a  to perform the first division. With its rotation, a protruded wiring board portion  2   j  that protrudes from one edge (right edge) of the conveying chute  55  is forced up by the lower clamp claw  58  so that the portion to be divided is brought into contact with the fulcrum  56   a  of the support body  56 . As shown in  FIG. 13 ( c ), the clamper  59  is further raised so that bending stress is applied to the protruded wiring board portion  2   j  about the fulcrum  56   a . Thus, the substrate  2   a  is perfectly divided as described above and a division section  62  cuts into a resin layer  3   a . At this time, however, a non-divided resin portion  3   s  remains in the resin layer  3   a  as described above and hence the substrate  2   a  is brought to a perfectly non-divided state. Incidentally, the center of rotation  67  is indicated by a black circle in FIGS.  13 ( a ) to  13 ( d ). The center of rotation  67  overlaps the fulcrum  56   a.    
      Next, as shown in  FIG. 13 ( d ), the clamper  59  is rotated in the reverse direction to allow the upper clamp claw  57  to push down the protruded wiring board portion  2   j  to perform the second division. The clamper  59  is rotated and moved downward at an angle of about 35° about the fulcrum  56   a  from the origin position thereof. That is, the clamper  59  is rotated by 90° from the origin position by the forward rotation and thereafter reversely rotated by 125°. As a result, the substrate  2   a  is brought to a state being held by the right edge of the conveying chute  55  and the conveying claw  60  or the support body  56 . Then, the clamper  59  is further rotated in the reverse direction so that tensile stress is applied to the non-divided resin portion  3   s  as shown in the lower right enlarged drawing of  FIG. 13 ( d ). That is, the end faces of the divided substrates  2   a  constituted of ceramic firstly collide with each other due to bending and hence tensile stress acts on the non-divided resin portion  3   s . Thus, the leading end of a division section (division line)  62  continues to extend to the non-divided resin portion  3   s , whereby the non-divided resin portion  3   s  is also divided perfectly at the end. This occurs instantaneously. Thus, the strip body  2   g  is formed as shown in  FIG. 10 . The strip body  2   g  results in such a structure that the areas (product forming sections) are arranged in a row.  
       FIG. 14  is a typical view showing a substrate one-row division illustrative of a modification of the first embodiment. In  FIG. 14 , grooves (division grooves)  3   p  are defined even in the surface of a resin layer  3   a  in association with the division grooves  2   p  to make it easy to perform the division, thereby making it easier to carry out the division. Forming the division grooves  3   p  in the surface of the resin layer  3   a  in this way makes it possible to accurately determine each division position (division line) in cooperation with the existence of the division grooves  2   p  and make constant the size of a finally formed semiconductor device  1 .  
      The fail mark detecting stage B and the individual division stage C will next be described with reference to  FIGS. 15 through 18  and FIGS.  22 ( a ) to  22 ( d ). The strip body  2   g  formed by one-row division in the one-row dividing stage A is conveyed onto the conveying chute  55  in which the fail mark detecting stage B and the individual division stage C exist, by means of an unillustrated conveying mechanism. The conveying mechanism serves as, for example, a motor-driven conveyance claw-feeding mechanism often used in general. A mechanism including the conveying chute  55 , a support body  56  having a fulcrum  56   a  placed over the right edge of the conveying chute  55 , and a clamper  59  disposed on the extension side of the right edge of the conveying chute  55  is shown in  FIGS. 15 and 16 . Since the individual division mechanism is similar in structure to the one-row division mechanism, similar component parts use the same names as those of the one-row division mechanism, and reference numerals will be explained with being marked with dashes or apostrophes (&#39;). In particular, the description of the component parts identical in configuration and operation to the one-row division mechanism will be omitted.  
      The conveying chute  55  of the individual division mechanism is provided with a fail mark detection mechanism for detecting the presence or absence of a fail mark on the lower surface of the strip body  2   g . The clamper  59  of the individual division mechanism is provided with a structure having a selection mechanism for eliminating a product (semiconductor device) with a fail mark upon individual division. The clamper  59  takes such a configuration (slide configuration) that the clamper  59  is slid to the side and switched when it receives the semiconductor device with the fail mark.  FIGS. 15 and 16  are drawings illustrative of such an attitude that the clamper receives a semiconductor device with no fail mark.  FIGS. 17 and 18  are drawings illustrative of such an attitude that the clamper receives a semiconductor device provided with a fail mark and causes it to pass to thereby allow a defective product storage box  88  to hold the corresponding defective semiconductor device.  
      As shown in  FIG. 15 , a clamper  59 ′ having an upper clamp claw  57 ′ and a lower clamp claw  58 ′ is located on the extension side of the right end of a conveying chute  55 ′ extending in the horizontal direction. As shown in  FIG. 16 , a support body  56 ′ is disposed slightly above the right end of the conveying chute  55 ′.  
      In order to cause the conveying chute  55 ′ to guide a slender strip body  2   g , a pair of guide pieces  83  is disposed over the upper surface of the conveying chute  55 ′ so as to have an interval therebetween, which allows one strip body  2   g  to pass and guide. The guide pieces  83  are fixed to the conveying chute  55 ′ with bolts  84 .  
      Part of the conveying chute  55 ′ through which the strip body  2   g  passes, takes a structure which is formed in a transparent body  85  and detects whether a fail mark exists in each of areas (product forming sections) of the strip body  2   g , by a fail mark detection mechanism disposed below the conveying chute  55 ′. The fail mark detection mechanism comprises a projector  86  which applies light onto the transparent body  85 , and a monitor camera  87  which detects the lower surface of the strip body  2   g . Information of the fail mark detection mechanism is transmitted to a control system where it is processed. A selection mechanism is operated based on this information to allow a defective product to drop and put in the defective product storage box  88  located below the clamper  59 ′ as shown in  FIG. 18 .  
      The support body  56 ′ of the individual division mechanism is small in division force as compared with the support body  56  of the one-row division mechanism. Thus, the rigidity of the support body  56 ′ may be smaller than that of one employed in the one-row division mechanism. The support body  56 ′ can be configured as a structure which is as thin as approximately 3.5 mm, for example. The support body  56 ′ has the advantage that a spatial region above the support body  56 ′ can be used effectively. Both ends of the support body  56 ′ are respectively fixed to the guide pieces  83  with bolts  84 . The support body  56 ′ may be a single-sheet structure or a double-sheet structure or the like.  
      A support block  68 ′ controlled so as to rotate forward and backward by a division swing motor  73 ′ slidably controls the lower clamp claw  58 ′ in the direction (transverse direction) normal to the direction of conveyance of the strip body  2   g . The lower clamp claw  58 ′ is fixed onto a slide section  89 , and the slide section  89  slides on the support block  68 ′. A slide mechanism is omitted. The individual division mechanism is configured so as to directly connect a drive pulley  75 ′ of the division swing motor  73 ′ to a rotatable shaft  71   a ′ by a coupling  95 ′ to rotate the support block  68 ′ forward and backward.  
      Three slender guide pieces  90  are fixed to the lower clamp claw  58 ′ with screws. For example, a defective product chute  92  is formed of the central guide piece  90  and the guide piece  90  provided on the right side as viewed in the travelling direction of the strip body  2   g . The state of  FIG. 15  shows the manner in which a non-defective product chute  91  is capable of receiving each non-defective product. The non-defective product chute  91  is provided with a stopper  93 , which is positioned onto the non-defective product chute  91  so as to receive a semiconductor device  1  slid within the inclined non-defective product chute  91 .  
      Under the attitude that each defective product is accepted, the lower clamp claw  58 ′ is slid toward the left side as viewed in the travelling direction of the strip body  2   g . Thus, the defective product chute  92  receives divided and fractionalized semiconductor devices  1  as shown in  FIG. 17 . The defective product chute  92  is provided with no stopper. Thus, the semiconductor devices  1 , which drop with being slid on the inclined non-defective chute  92 , are accommodated in the defective product storage box  88  as shown in  FIG. 18 .  
      As shown in  FIG. 15 , the upper clamp claw  57 ′ extends longer than the lower clamp claw  58 ′ in such a manner that the upper clamp claw  57 ′ always faces the sliding lower clamp claw  58 ′, and has both ends fixed to the support block  68 ′ with screws.  
       FIG. 15  shows the attitude of the clamper  59 ′ which accepts each non-defective product, and  FIG. 16  shows the state of the clamper  59 ′ returned to its origin position before the starting of the individual division or after its completion.  FIG. 17  shows the attitude of the clamper  59 ′ which accepts or takes up each defective product, and  FIG. 18  shows the state of the clamper  59 ′ which performs the individual division and is held in an inclined state.  
      FIGS.  22 ( a ) through  22 ( d ) show fractionalization by the first division and the second division in the individual division mechanism, i.e., a method of forming each semiconductor device  1 . As shown in  FIG. 22 ( a ), a strip body  2   g  is positioned and placed over the upper surface of its corresponding conveying chute  55 ′.  
      Next, as shown in  FIG. 22 ( b ), the clamper  59 ′ is rotated by about 120° (forward-rotated) upward about the fulcrum  56   a ′ to perform the first division. With its rotation, a protruded wiring board portion  2   j ′ that protrudes from one edge (right edge) of the conveying chute  55 ′ is forced up by its corresponding lower clamp claw  58 ′ so that the portion to be divided is brought into contact with the fulcrum  56   a ′ of the support body  56 ′. As shown in  FIG. 22 ( c ), the clamper  59 ′ is further elevated so that bending stress is applied to the protruded wiring board portion  2   j ′ about the fulcrum  56   a ′. Thus, the strip body  2   g  is perfectly divided as described above and a division section  62 ′ cuts into a resin layer  3   a . At this time, however, a non-divided resin portion  3   s ′ remains in the resin layer  3   a  as described above and hence the strip body  2   g  is brought to a perfectly non-divided state. Incidentally, the center of rotation  67 ′ is indicated by a black circle in FIGS.  22 ( a ) to  22 ( d ). The center of rotation  67 ′ overlaps the fulcrum  56   a′.    
      Next, as shown in  FIG. 22 ( d ), the clamper  59 ′ is rotated in the reverse direction to allow the upper clamp claw  57 ′ to push down the protruded wiring board portion  2   j ′ to perform the second division. The clamper  59 ′ is rotated and moved downward at an angle of about 30° about the fulcrum  56   a ′ from its origin position. That is, the clamper  59 ′ is rotated by 120° from the origin position by the forward rotation and thereafter reversely rotated by approximately 150°. As a result, the strip body  2   g  is brought to a state being held by the right edge of the conveying chute  55 ′ and the corresponding conveying claw  60 ′ or support body  56 ′. Then, the clamper  59 ′ is further rotated in the reverse direction so that tensile stress is applied to the non-divided resin portion  3   s ′ as shown in the lower right enlarged drawing of  FIG. 22 ( d ). That is, the end faces of the divided substrates  2   a  constituted of ceramic firstly collide with each other due to bending and hence tensile stress acts on the non-divided resin portion  3   s ′. Thus, the leading end of a division section (division line)  62 ′ continues to extend to the non-divided resin portion  3   s ′, whereby the non-divided resin portion  3   s ′ is also divided perfectly at last. The extension of the division section (division line)  62 ′ occurs instantaneously. Thus, each substrate  2   a  results in a module substrate  2  by the individual division, and resin layer  3   a  results in an encapsulating body  3 .  
      The slide position of the lower clamp claw  58 ′ is controlled based on the information of the fail mark detection mechanism. Thus, each semiconductor device  1  taken as non-defective is placed over the non-defective product chute  91  of the lower clamp claw  58 ′, whereas each semiconductor device  1  regarded as defective is recovered into the defective product storage box  88 .  
      Although only the lower clamp claw  58  has such a structure as to slide laterally upon elimination of each product with the fail mark in the present embodiment, both the upper clamp claw  57  and the lower clamp claw  58  may take such a structure as to slide laterally.  
      The semiconductor devices  1  placed in the individual division stage C are sequentially pick-up conveyed onto subsequent plural stages by an individual conveying mechanism  97 . In  FIG. 10 , the individual conveying mechanism  97  is configured so as to cause five arms  98  to extend on the stages, adsorb and hold the semiconductor devices  1  under vacuum by vacuum adsorption tools attached to portions below their leading ends although not shown in the drawing and convey the same to the next stage.  
      A thickness detection mechanism is disposed in the thickness detecting stage D. As shown in  FIG. 23 , a laser sensor  101   a  and a photoreceptor  101   b  are placed at the side face of a stage  100  of the thickness detecting stage D. The thickness of the semiconductor device  1  placed over the stage  100  is measured according to the irradiation of laser light  102  and the amount of light reception. Such measured information is transmitted to a control system where it is processed. A computing process related to it is performed by the control system to make a decision as to a non-defective/defective product. This information is stored. The final stage is provided with a pickup mechanism which picks up semiconductor devices  1  and which conveys a non-defective product to a non-detective product storage unit and conveys a defective product to a defective product storage unit. The thickness detection information is also equivalent to one information which determines by the pickup mechanism whether each product is good or bad. If the product is determined as defective, then even ones judged to be non-detective by other detection information are conveyed to a defective product storage unit.  
      A positioning mechanism is placed in the positioning stage E. As shown in  FIG. 24 , a pair of positioning claws  106 , which approaches a square-shaped semiconductor device  1  placed-over a stage  105  of the positioning stage E and is spaced away therefrom over one diagonal section  24  of the square semiconductor device  1 , is provided in association with the semiconductor device  1 . Recesses  107  whose bottoms are formed as right-angle recesses and which correspond to a pair of corners of the square-shaped semiconductor device  1 , are respectively provided at the faced leading-end surfaces of the pair of positioning claws  106 . Thus, the pair of positioning claws  106  is flexibly moved relative to the center in association with the semiconductor device  1  placed over the stage  105 , so that the center of the semiconductor device  1  is positioned to the center of the stage  100 , whereby its positioning is completed. Although the positioning is done by means of the pair of two positioning claws in the present embodiment, the present invention is not limited to it. For example, a method of performing positioning by four positioning claws may be adopted.  
      A size detecting mechanism for detecting the size of each semiconductor device is provided in the size detecting stage F. As shown in  FIG. 25  and FIGS.  26 ( a ) through  26 ( c ), a stage  110  of the size detecting stage F has a detection hole  111  having a predetermined size, which penetrates the stage  110  up and down. A vertical shaft  112  controlled so as to move up and down is inserted into the detection hole  111 . An upper end of the vertical shaft  112  serves as a base  113 , which places the semiconductor device  1  thereon.  
      A pocket section  114 , which guides the semiconductor device  1  toward the center, is provided at the upper end portion of the detection hole  111 . The detection hole  111  serves as a hole analogous to the semiconductor device  1 , which can be inserted through a slight clearance or gap. The detection hole  111  serves as, for example, a hole larger by about 170 μm than the designed size of the semiconductor device  1 . One, which cannot be inserted within the detection hole  111  and is inclined within the detection hole  111  as shown in  FIG. 26 ( c ), is judged to be defective in size.  
      The pocket section  114  is formed by quadrangular pyramid-shaped recess analogous to the semiconductor device  1  and guides the semiconductor device  1  conveyed to the stage  111  to the detection hole  111 .  
      The stage  110  is shaped in the form of a cylindrical body whose upper portion becomes thin over two stages. At an upper cylindrical section  115  of the upper stage, a plurality of light-transmitted holes  116  are provided so as to intersect the detection hole  111 . In FIGS.  26 ( a ) to  26 ( c ), three light-transmitted holes  116  are provided. Projectors (light emitters)  117  are provided at the outer ones of the respective light-transmitted holes, whereas photodetectors  119  which receive light  118  emitted from the projectors  117 , are provided at the outer others thereof. One light-transmitted hole  111  is provided in one direction, and two light-transmitted holes  111  are provided in parallel in the direction normal to it, thereby enhancing reliability of size detection. The projectors  117  and the photodetectors  119  are mounted above mounting holes  121  defined in the middle cylindrical section  120 . Power supply lines  117   a  and  119   a  connected to the projectors  117  and the photodetectors  119  are connected to a control system such as a predetermined controller through the mounting holes  121 .  
      Upon size detection, the semiconductor device  1  is conveyed to the pocket section  114  of the size detecting stage  110 . As shown in  FIG. 26 ( a ), the vertical shaft  112  that accepts the semiconductor device  1  is elevated and stops at a predetermined height, where its upper end is positioned to the lower portion of the pocket section  114 . Therefore, the semiconductor device  1  conveyed within the pocket section  114  is guided to the pocket section  114 , so that the semiconductor device  1  is placed over the upper end of the vertical shaft  112 .  
      Next, as shown in  FIG. 26 ( b ), the vertical shaft  112  is lowered to a predetermined height (reference position). In this state, the light  118  passes over the semiconductor device  1  in the case of the semiconductor device  1  placed closely over the flat base  113  of the vertical shaft  112 . Therefore, the light  118  can be received by the corresponding photodetector  119 . This light-receivable state is defined as a non-defective product. When the semiconductor device  1  cannot be inserted into the detection hole  111  and is inclined over the base  113  as shown in  FIG. 26 ( c ), the light  118  emitted from the corresponding projector  117  is struck on the semiconductor device  1  and does not reach the corresponding photodetector  119 . This results in size defective information.  
      Measured information about the size is conveyed to the control system where it is processed. A computing process related to it is performed by the control system to make a decision as to a non-defective/defective product. This information is stored. This results in designation information which sorts the non-defective/defective products by the pickup mechanism which picks up the semiconductor device  1  at the final stage. Thus, the size detection information is also equivalent to one information which determines by the pickup mechanism whether each product is good or bad. If the product is determined as defective, then even ones judged to be non-detective by other detection information are conveyed to a defective product storage unit.  
      The pickup mechanism is disposed over the size detecting stage F, the non-defective product holding stage G and the defective product holding stage H. The pickup mechanism is configured so as to convey the held semiconductor device  1  to the non-defective product storage unit of the non-defective holding stage G or the defective product storage unit of the defective product holding stage H on the basis of information about whether the flatness of the semiconductor device  1  picked up by the size detecting stage F is good or bad, based on the detection of its flatness by a pickup mechanism to be described later, and go/no-go information of the thickness detection/size detection.  
      As shown in  FIG. 27 , a pickup mechanism  124  has a tool (nozzle)  125  which vacuum-adsorbs a semiconductor device  1  onto its lower end surface. The tool  125  is three-dimensionally moved and controlled by a drive unit  126  as shown in  FIG. 10 . That is, the tool  125  is attached to a leading lower surface of an arm  127  corresponding to part of the drive unit  126 . The arm  127  is three-dimensionally moved by the drive unit  126 . As shown in  FIG. 27 , a tubing or pipe arrangement  128  is connected to the tool  125  and a vacuum source  129  is connected to the tubing  128 . A solenoid-operated valve  130 , which performs an on/off operation by the control system, and a flow throttle valve  131  are connected to the midway points of the tubing  128  in a communicating state. A digital vacuum meter  132 , which measures the degree of vacuum in the tool  125 , is connected to the tubing  128  between the solenoid-operated valve  130  and the tool  125 .  
      When the semiconductor device  1  is picked up at the size detecting stage F, the degree of vacuum in the tool  125  is measured. In  FIG. 27 , the stage  10  of the size detecting stage F is simply indicated by a line. The tool  125  adsorbs and holds under vacuum the surface side of an encapsulating body  3  formed of a resin, of the semiconductor device  1 . Therefore, the degree of vacuum measured by the digital vacuum meter  132  varies greatly in the case of such a silicone resin that its surface is undulated or waved.  
      FIGS.  28 ( a ) and  28 ( b ) are typical views showing a vacuum adsorbed state of a product judged as a non-defective product by the pickup mechanism  124  and the state of flatness of the surface of an encapsulating body  3 .  FIG. 28 ( b ) shows the flatness at a predetermined thickness of the encapsulating body  3 . The difference between a low spot and a high spot is less than or equal to 100 μm. Incidentally, the sizes a and b of the encapsulating body  3  in  FIG. 28 ( b ) are a =7 mm and b 7 mm, for example.  
      When the flatness of the surface of a silicone resin, corresponding to the surface of the encapsulating body  3  is satisfactory as shown in  FIG. 28 ( b ) where a semiconductor device  1  is adsorbed under vacuum by the vacuum adsorption surface of the lower end of the tool  125 , a ring  125   a  formed of an elastic body, which is lying in the vacuum adsorption surface, contacts the encapsulating body  3  substantially over the full circumference, and vacuum leakage is less reduced, thereby enhancing the degree of vacuum (pressure of vacuum) in the tool  125 .  
      FIGS.  29 ( a ) and  29 ( b ) are typical views showing a vacuum adsorbed state of a product judged as a defective product by the pickup mechanism  124  and the state of flatness of the surface of an encapsulating body  3 .  FIG. 29 ( b ) shows the flatness at a predetermined thickness of the encapsulating body  3 . The difference between a low spot and a high spot reaches 150 μm.  
      When the flatness of the surface of a silicone resin, corresponding to the surface of the encapsulating body  3  is not satisfactory as shown in  FIG. 29 ( b ) where a semiconductor device  1  is adsorbed under vacuum by the vacuum adsorption surface of the lower end of the tool  125 , some of a ring  125   a  is not brought into contact with the encapsulating body  3  and a gap  133  defined therebetween also becomes large. Thus, atmosphere air flows into the tool  125  so that the degree of vacuum (pressure of vacuum) in the tool  125  is reduced.  
      Therefore, the degree of vacuum in the tool  125  is measured. Information about the measured degree of vacuum is sent to the control system. The control system judges the semiconductor device  1  as a flatness defective product where the degree of vacuum is a degree of vacuum less than the predetermined reference degree of vacuum, judges the semiconductor device  1  as a non-defective product where the degree of vacuum is a degree of vacuum greater than or equal to the reference degree of vacuum, and controls the pickup mechanism based on the results of judgements referred to above.  
      On the other hand, a tray  135  is placed in the non-defective product holding stage G as a non-defective product storage unit. A defective product storage box  136  is placed in the defective product holding stage H as a defective product storage unit. Thus, when any of the thickness detection information, size detection information and flatness detection information is regarded as defective, the pickup mechanism  124  conveys the corresponding semiconductor device  1  to the defective product storage box  136  under the control of the control system. When all the information are judged as satisfactory, the corresponding semiconductor device  1  is accommodated in the tray  125  as a non-defective product. As shown in  FIG. 10 , a rack  138  for holding or accommodating the tray  135  is placed in the non-defective product holding stage G. The tray  135  is pitch-fed from the rack to a non-defective product storage position. When the tray  135  becomes full, it is delivered to a tray recovery table  139 . The tray  135  lying on the tray recovery table  139  is transferred to a predetermined location.  
      According to the first embodiment, the following advantageous effects are brought about.  
      (1) A resin layer  3   a  formed by printing of a silicone resin is printed and thereafter subjected to defoaming processing and curing processing (bake processing). A heavy substance such as a filler contained in a resin at the defoaming processing long in processing time sinks from the upper surface side to the substrate (wiring board)  2   a  side at its lower surface. As a result, the surface of the resin layer  3   a  is brought to a layer of a resin component hard to tear off. Thus, a compression force merely acts on the layer of the resin component in the surface layer of the resin layer  3   a  even if the substrate  2   a  is divided, in the case of such a division that the substrate  2   a  is folded back to the resin layer  3   a  side. Therefore, the resin portion remains without the division of the substrate  2   a  (non-divided resin portion remains). In a dividing method and a semiconductor manufacturing apparatus according to the present invention, a protruded wiring board portion  2   j  of a wiring board (substrate  2   a , strip body  2   g ) formed of ceramic is forced up (upper swing) by means of a lower clamp claw  58  of a clamper  59 , and some of the protruded wiring board portion  2   j  is pressed against a support body to carry out a first division under bending stress. Thereafter, the upward-located clamper  59  is rotatably swung (lower swing) downward to allow an upper clamp claw  57  to press down the protruded wiring board portion  2   j , thereby performing a reverse-division at the first division section again as a second division. Since the second division allows a tensile force to act on a remaining and thin non-divided resin portion  3   s , the non-divided resin portion  3   s  is torn off. Thus, the perfect division is enabled. Fractionalizing is done by a one-row division and an individual division so that each semiconductor device  1  is manufactured.  
      (2) In the one-row division and the individual division, the division position of each wiring board is determined at a fulcrum  56   a , and division positions (division lines) are determined by division grooves  2   p  defined in the wiring board. Therefore, it is possible to make constant the size of a finally-formed semiconductor device  1 . Thus, the reliability of mounting at users is enhanced.  
      (3) Since the cut residual of the resin layer  3   a  is set to less than or equal to 0.1 mm upon the upper swing, the wiring board can be separated without applying a load than required to the wiring board upon the lower swing. Accordingly, a resin package product stable even in view of the quality can be provided.  
      (4) The semiconductor manufacturing apparatus according to the present embodiment has a structure in which the clamper  59  that forces up the protruded wiring board portion  2   j  or presses down the protruded wiring board portion  2   j  do not hold the protruded wiring board portion  2   j  with the protruded wiring board portion  2   j  being directly pinched thereby. Although the wiring board placed over the conveying chute  55  is also held with being interposed between the conveying chute  55  and the fulcrum  56   a  of the support body  56 , no electronic part exists in this division section. Owing to these, the division can be performed without damaging the wiring board and mounting parts, and hence a resin package product excellent in quality can be provided.  
      According to the first embodiment as apparent from the above (1) through (4), a failure in division is hard to occur, and a high reliable semiconductor device can be provided. It is also possible to achieve yield enhancement. As a result, a semiconductor device excellent in quality can be provided at low cost. It is possible to provide, for example, a semiconductor device for a cellular phone.  
      (5) In the semiconductor manufacturing apparatus according to the first embodiment, a pickup mechanism  124 , which conveys products brought to semiconductor devices  1  by being fractionized, vacuum-adsorbs and holds a semiconductor device  1  at a final stage by a tool  125  but measures the degree of vacuum in its held state. Then, the pickup mechanism  124  is controlled based on information about the degree of vacuum. When the measured degree of vacuum is greater than or equal to the reference degree of vacuum, the pickup mechanism  124  conveys the semiconductor devices  1  to the corresponding non-defective product storage unit. When the degree of vacuum is less than the reference degree of vacuum, the pickup mechanism  124  conveys the semiconductor devices  1  to the corresponding defective product storage unit. Thus, only products in each of which the flatness of the surface of an encapsulating body  3  is satisfactory, can be shipmented. As a result, the pickup of each semiconductor device  1  is done reliably upon the work of mounting of the semiconductor device  1  by a user, thus making it possible to carry out satisfactory mounting.  
      (6) The semiconductor manufacturing apparatus according to the present embodiment has an excellent feature in that a substrate  2   a  whose surface is provided with a fail mark in a state being formed with a resin layer  3   a , is detected in a state of a strip body  2   g , and when the strip body  2   g  is divided and fractionalized, the fractionalized ones can be selected and eliminated.  
      (7) The semiconductor manufacturing apparatus according to the present embodiment has another excellent feature in that since the thickness of each individualized semiconductor device  1  can be detected and each defective product can be eliminated by the pickup mechanism  124 , only non-defective products can be accommodated into the tray  135 .  
      (8) The semiconductor manufacturing apparatus according to the present embodiment has a further excellent feature in that since the size of each individualized semiconductor device  1  can be detected and each defective product can be eliminated by the pickup mechanism  124 , only non-defective products can be accommodated in the tray  135 .  
      (9) The semiconductor manufacturing apparatus according to the present embodiment is capable of accurately and reliably dividing the substrate  2   a  and the strip body  2   g . Semiconductor devices  1  with fail marks attached thereto in advance can be eliminated upon fractionalization. Further, the pickup mechanism  124  is capable of performing defective product elimination, based on thickness detection information, size detection information and flatness detection information detected at respective detecting stages. Thus, the semiconductor manufacturing apparatus according to the present embodiment has a still further excellent feature in that a semiconductor device  1  excellent in quality can be manufactured with high yields.  
      (10) The implementation of automatic division enables mass production of resin package products, makes it easy to enlarge a mounting area around a substrate and adapt to its size, and makes it possible to adapt to a size reduction and package diversification.  
      (11) With the use of the semiconductor manufacturing apparatus according to the first embodiment, the manufacture of a low elastic resin-sealed product can also be established which is capable of preventing a short caused by re-melting of solder within the encapsulating body  3  upon secondary mounting by customers.  
      (12) With the use of the semiconductor manufacturing apparatus according to the first embodiment, it is possible to improve the quality of a semiconductor device and reduce the machining cost thereof.  
      (13) With the use of the semiconductor manufacturing apparatus according to the first embodiment, a high frequency module product can also be reduced in cost.  
      (14) With the use of the semiconductor manufacturing apparatus according to the first embodiment, TAT (Turn around Time: product development period) can be shortened.  
      (15) Laser- or dicing-based division involves the problem that a cut section becomes white due to the fly-off and adhesion of cuttings or chips and the cutting of contained silica. In contrast, the present embodiment is capable of obtaining a clean divided surface.  
     Second Preferred Embodiment  
      A second embodiment shows an example in which in a semiconductor manufacturing apparatus, the division of a wiring board is made satisfactory and the position to divide the wiring board can be set accurately. FIGS.  30 ( a ) and  30 ( b ) is a typical view illustrating a cutting mechanism for cutting a substrate covered with a resin layer and its cut state.  
      As described in the first embodiment, the surface of the resin layer  3   a  formed by printing is low in flatness due to an undulation or the like. When the undulation is large, a resin layer  3   a  is not brought into contact with a fulcrum  56   a  of a support body  56  when a protruded wiring board portion  2   j  of a substrate  2   a  is forced up, and a top portion  142  of an undulation  141  comes into contact with the lower surface of the support body  56 , as shown in  FIG. 31 . It has turned out that since the position to which a dividing force is applied, does not correspond to the position of the fulcrum  56   a  in such a case, the division does not necessarily start from the position of each division groove  2   p  even if the division groove  2   p  is located substantially directly below the fulcrum  56   a , thereby causing the fear that the division position is not specified.  
      The second embodiment shows the technique of resolving the above failure in division. In the second embodiment, the support body  56  is configured such that a lower surface thereof provided face-to-face to a conveying chute  55  becomes a flat surface as shown in  FIG. 30 ( a ). A protruding strip body  143 , which protrudes toward the conveying chute  55 , is provided at the right end of the lower surface of the support body  56 . The protruding strip body  143  takes such a tapered section that it becomes thin gradually downward. The protruding strip body  143  is made wide so as to be capable of linearly contacting and supporting a wide substrate  2   a  and a strip body  2   g  for the purpose of their division. The leading edge of the protruding strip body  143  forms a fulcrum  56   a.    
      According to such a division mechanism, when a clamper  59  is swung upward as shown in  FIG. 30 ( b ), a lower clamp claw  58  forces up a protruded wiring board portion  2   j . With its upper swing, the fulcrum  56   a  corresponding to the leading end of the protruding strip body  143  is first brought into contact with the surface of a resin layer  3   a . Since the leading end of the protruding strip body  143  is sharp, the protruding strip body  143  is engaged in the resin layer  3   a  in some degree. However, the position where it is engaged therein, corresponds to such a position as to face each division groove  2   p . Therefore, division can be performed at the division grooves  2   p  accurately and reliably. Thus, the size of a semiconductor device  1  is always kept constant.  
      As is understood from the above description, the protruded length of the protruding strip body  143  is set to such a length that the surface of the resin layer  3   a  is not brought into contact with the lower surface of the support body  56  in a state in which the leading end of the protruding strip body  143  has been brought into contact with the grooves (division grooves)  2   p  and engaged therein.  
       FIG. 32  shows a modification of the second embodiment of the present invention. The present example serves as a mechanism considered in such a manner that one surface of a protruding surface of a protruding strip body  143  is set to a surface normal to an upper surface of a conveying chute  55 , and the top or protruding portion of an undulation of a resin layer  3   a  is made hard to contact a lower surface of a support body  56  connected to its vertical surface  144  and the vertical surface  144 , thereby carrying out partition satisfactorily.  
      While the invention made above by the present inventors has been explained specifically based on the embodiments, the present invention is not limited to the embodiments. It is needless to say that various changes can be made thereto within the scope not departing from the gist thereof.