Abstract:
A manufacturing method for fabricating integrated electronic circuits on a semiconductor support provides a plurality of integrated circuits and provides a plurality of scribing lines. The scribing lines are located such that the electronic circuits are regularly spaced apart by the scribing lines. A network of electrical connection lines is provided in at least one of the scribing lines. Metallization strips are provided in the scribing lines as electrical connection lines, and the electrical connection lines are connected to the integrated circuit. At least one current limitation element is provided between the electrical connection line and the integrated circuit. In this manner it is possible to simultaneously perform electrical testing of all the circuits present on the same wafer.

Description:
TECHNICAL FIELD 
     The present invention relates to a manufacturing method for electronic circuits, and more particularly to a manufacturing method for electronic circuits monolithically integrated on a semiconductor support on which the electronic circuits are regularly arranged side by side and separated by dividing grooves, and to a semiconductor wafer incorporating a plurality of the electronic circuits. 
     BACKGROUND OF THE INVENTION 
     As is known, the production process leading to the provision on a large scale of integrated electronic circuits includes a number of processing steps which take place on a thin wafer of semiconductor material, e.g., a monocrystalline silicon wafer. The waver is subjected to a number of chemical and physical treatments and to photolithographic processes which lead to the definition of a complex three-dimensional topography constituting the integrated circuit architecture. 
     A single wafer can contain hundreds of identical integrated circuits commonly called chips and arranged regularly side by side and separated by scribing lines. In the annexed FIG. 1 is shown schematically a top view of a wafer incorporating a so-called chip matrix. 
     The processing of a wafer ends with electrical testing. Before the circuits are separated by sectioning the wafer, each circuit is tested to check if it operates correctly. Indeed, since it is impossible to avoid the presence of defects in the wafer, a certain percentage of circuits will exhibit defects or faults that may compromise their correct operation. Even a single defect can rain an entire circuit. A scratch of a few micrometers, or even a single grain of dust, can break a connection. 
     The most common failure state afflicting the semiconductor chips is the presence of short circuits inside the integrated structure. 
     The electrical testing is performed automatically by a test machine managed by a computer that rapidly checks one circuit after another and marks the defective ones to indicate that they are to be rejected. It is not possible to repair the defective circuits which are to be rejected. Otherwise, they would be uselessly subjected to subsequent costly operations of assembly and encapsulation in packages. 
     From this point of view it is necessary to take into consideration another important aspect of these problems. Some chips are subject to a phenomenon called &#34;infant mortality&#34; in which they pass the operation test but cease to operate shortly after being put into use. This type of failure, which takes place shortly after the first use of the circuits, is particularly harmful and a serious shortcoming for the manufacturer because the cost of additional inspection and encapsulation often exceeds the other production costs. 
     There is thus an unmet need in the art for a manufacturing method for integrated electronic circuits that allows easier, more economical, and rapid identification of defective circuits during the electrical inspection step and that overcomes the shortcomings which have limited the embodiments in accordance with the known art. 
     More specifically, there is also an unmet need in the art for a manufacturing method which allows identification and rejection of those circuits which would be subject to &#34;infant mortality&#34; and thus increases the quality of the entire final production. 
     SUMMARY OF THE INVENTION 
     The present invention provides a network of electrical connection lines used for diagnosis in the wafer of semiconductor material on which are provided the circuits. In this manner it is possible to simultaneously perform an electrical inspection of all the circuits present on the same wafer. 
     A manufacturing method for fabricating integrated electronic circuits on a semiconductor support provides a plurality of integrated circuits, and provides a plurality of scribing lines. The scribing lines are located such that the integrated circuits are regularly spaced apart by the scribing lines. A network of electrical connection lines is provided in at least one of the scribing lines. Metallization strips are provided in the scribing lines as electrical connection lines, and the electrical connection lines are connected to the integrated circuit. At least one current limitation element is provided between the electrical connection line and the integrated circuit. 
     The present invention also provides a wafer of semiconductor material having a plurality of integrated circuits. A plurality of scribing lines is positioned such that the integrated circuits are regularly spaced. A plurality of current limitation elements have at least a first current limitation element located in each of the integrated circuits. A plurality of electrical connection lines has at least a first electrical connection line located in at least one of the scribing lines. The first electrical connection line is coupled to the first current limitation element of at least one integrated circuit adjacent to the first electrical connection line, and the first electrical connection line is electrically connectable to a first voltage source. 
     The characteristics and advantages of the method in accordance with the present invention are set forth in the description of an embodiment thereof given below by way of non-limiting example with reference to a wafer of semiconductor material incorporating integrated electronic circuits and illustrated in the annexed drawings. 
    
    
     BRIEF DESCRIPTION OF THE DRAWINGS 
     FIG. 1 shows schematically a top view of a wafer or wafer of semiconductor material incorporating a plurality of integrated electronic circuits; 
     FIG. 2 shows schematically in enlarged scale a group of integrated electronic circuits provided in accordance with the method of the present invention on the wafer of FIG. 1; 
     FIG. 3A shows a detail of an electrical diagram of one embodiment of the integrated electronic circuits of FIG. 2; 
     FIG. 3B shows a detail of an electronic diagram of another embodiment of the integrated electronic circuits of FIG. 2; 
     FIG. 4A shows schematically in even larger scale a detail of the group of integrated electronic circuits of FIG. 3A; 
     FIG. 4B shows schematically in even larger scale a detail of the group of integrated electronic circuits of FIG. 3B; and 
     FIG. 5 shows in enlarged scale and vertical cross section of a partial detail of the wafer of FIG. 1 taken generally along plane of cut V--V of FIG. 2 but showing only a single metallization strip. 
    
    
     DETAILED DESCRIPTION OF THE INVENTION 
     FIG. 1 shows a thin wafer 1 of semiconductor material, e.g., a wafer of silicon on which have been provided multiple integrated circuits 2. The integrated circuits 2 are essentially square or rectangular in shape with a few millimeters per side and can be digital, analog, or power type. The integrated circuits 2 are separated from each other by a groove 11, i.e., a dividing line of approximately 200 μm termed a &#34;scribing line&#34; and present between one integrated circuit 2 and the next. The scribing line 11 completely surrounds each integrated circuit 2. 
     As shown in FIG. 3A, each integrated circuit 2 includes a first control circuit portion 3 designed to operate at supply voltage Vcc, typically +5 volts. A second power circuit portion 4 is in turn integrated in the circuit 2 in connection with the first control circuit portion 3. As shown in FIG. 3B, this second power circuit portion 4 is designed to operate at a supply voltage Vd, higher than supply voltage Vcc and typically +12 volts. However, as shown in FIG. 3A, power circuit portion 4 can also operate at supply voltage Vcc. 
     For the sake of simplicity of discussion the power circuit portion 4 has been diagrammed in FIGS. 3A and 3B with a single power transistor M1 having a control terminal G connected to an output of the first control circuit portion 3. Of course the power circuit portion 4 can be structured in a much more complex manner. The transistor M1 can be of the DMOS type and the integrated circuit 2 can be provided with BCD technology. 
     As shown in FIG. 2, every integrated circuit 2 includes a number of terminals or pads 5, which are provided to allow electrical connection of the integrated circuit 2 to the associated connection pins during assembly in the supporting package once the circuit has been cut from the wafer. As shown in FIG. 3, a first pad 6 is provided to receive the supply voltage Vcc of the control circuit portion 3, a second pad 7 is provided to receive the supply voltage Vd of the power circuit portion 4, and a third pad 8 is designed for connection with another voltage reference, e.g., a signal ground GND. The pads 6, 7 and 8 are powered with different voltages only when the circuit is placed in operating condition. As shown in FIG. 2, in the greater part of cases the pads 6 and 7 are located near one side of the integrated circuit 2 opposite that side near which the pad 8 is located. 
     FIG. 2 shows additional pads 9 and 10, provided to allow diagnostic operations in accordance with the present invention and as described below. The pad 10 can coincide with a &#34;tristate&#34; terminal present in many integrated circuits and is generally positioned on a side of the integrated circuit 2 different from those on which are positioned pads 6, 7, and 8. Pad 10 is generally positioned on a side of the integrated circuit 2 opposite of the side with pad 9. 
     FIG. 2 shows that, in accordance with the present invention, inside and along the scribing lines 11 are provided connecting conducting line buses 12. Connecting conducting line buses 12 are connected between pads 6, 7, and 8 and their respective voltage sources Vcc, Vcc or Vd as appropriate, and GND. Connecting conductivity buses 12 also connect pads 9 and 10 to their respective signal sources. As shown in FIG. 1, connecting pads 18, 20, 22 and 23 on wafer 1 are connected to the connecting conducting line buses 12. During testing, a test station may be connected via probes to the wafer at pads 18, 20, 22 and 23. The pads 18, 20, 22, and 23 are connected to the appropriate wires within the bus 12 to connect the wafer to Vcc, Vd, GND, and diagnostic operation signals, respectively. If the bus 12 includes more than 4 metallized strips 13, additional pads 18, 20, 22, and 23 may be used. Of course, the pads 18, 20, 22, 23 can be positioned adjacent each other on one side of the wafer rather than at each edge. 
     FIG. 4A shows that connecting conducting line buses 12 can include connecting conducting lines 24 and 28. In this embodiment, connecting conducting line 24 connects pads 6 and 7 with supply voltage Vcc, and connecting conducting line 28 connects pad 8 with signal ground GND. Connecting conducting lines 30 and 32 can also be provided to connect pins 9 and 10 with their respective signal sources. FIG. 4B shows that in another embodiment, the connecting conducting line bus 12 can further include connecting conducting line 26, which connects pad 7 with Vd. 
     As shown in FIG. 5, the connecting conducting line buses 12 can be individual metallization strips 13. The metallization strips 13 are covered by a protective insulation layer 14, e.g., a layer of nitride or silicon oxide deposited by a P-Vapox process. Also, at intersections between the connecting conducting line buses 12 there are appropriate insulation layers above and below each metallization strip where they cross to ensure that the lines do not short out. The protective insulation layer 14 also insulates the metallization strips 13 from the surface of the semiconductor substrate 16. 
     At the end of the process leading to production and testing of the integrated circuits 2, the wafer is cut along the scribing line 11 by means of a very thin diamond blade which cuts along a cutting path nearly central and indicated by reference number 15 in FIGS. 4A and 4B. In this manner the individual integrated circuits 2 are separated to be subjected to subsequent assembly operations in conventional packages (not shown). As shown in FIGS. 4A and 4B, the connecting conductor line bus 12 extends inside the scribing lines 11 parallel to a horizontal axis but in a slightly off-center position in relation to the axis. The horizontal axis represents the cutting path 15 of the diamond blade used for separation of the integrated circuits 2. A vertical axis represents another cutting path 15 of the diamond blade. 
     FIGS. 4A and 4B also show that the first pad 6 of the supply voltage Vcc is electrically connected to connecting conducting line 24 by means of a current limitation element 17. The current limitation element 17 preferably includes a resistance R and a protection diode D serially connected to the resistance. Both the protection diode D and the resistance R are provided by means of diffusion or an equivalent technique, such as forming polysilicon resistors, inside each integrated circuit 2. Nothing prevents using as current limitation element 17 only the resistance R, of approximately 10 kohm, or a current generator of adequate value. 
     Normally the anode of the protection diode D is connected to the connecting conducting line bus 12 as shown in FIGS. 2, 3A, and 4A. However, in CMOS circuits for which there is a higher supply voltage Vd provided and the semiconductor substrate is held at the lower supply voltage Vcc, the previous connection must be reversed. In this case, the anode of protection diode D is connected to Vcc or ground through the integrated circuit 2. This configuration is shown in FIG. 3B and FIG. 4B. 
     As shown in FIG. 4B, the second pad 7 of the supply voltage Vd is also electrically connected to the connecting conducting line bus 12 by means of the series of a resistance R and a protection diode D. The value of the resistance R can be approximately 10 kohm. All the pads 6 and 7 of the integrated circuits 2 incorporated in the wafer 1 are connected in the above stated manner to the connecting conducting line bus 12 located near them, i.e., to the connecting conducting line bus 12 of the scribing line 11 adjacent to them. 
     Even the ground connection pads 8 are connected to a corresponding connecting conducting line bus 12, but this connection is the direct type and requires no protection diode. Normally the connecting conducting line 12 to which the pad 8 is connected is located in a parallel scribing line 11 on a side of integrated circuit 2 opposite the side where pads 6 and 7 are located. 
     The particular configuration of the wafer 1 which the semiconductor material assumes allows application of a diagnostic procedure described below. The purpose of this diagnostic procedure is to identify defective integrated circuits 2. 
     For this diagnostic procedure, the connecting conducting line buses 12 are powered in such a manner as to activate in parallel all the integrated circuits 2. A voltage of Vcc may be supplied to the integrated circuits 2; however, a voltage lower than Vcc may also be used. The circuit may be tested even if pad 6 is at a voltage lower than operating voltage for integrated circuit 2 due to a voltage drop across resistor R. Here, the purpose is determining whether a short circuit is present, not testing correct function of the integrated circuit 2. While the current required by each integrated circuit 2 is on the order of a few milliamps, the current supplied to the wafer 1 can be on the order of 1-2 amps. In this manner, the temperature is increased because, due to the Joule effect, the wafer containing hundreds of circuits dissipates electrical power in the form of heat. This operational step should be performed in an inert atmosphere, e.g., containing nitrogen. Further, the wafer should be heated above a standard temperature during testing. A high temperature should be provided by a burn-in oven, but the use of a burn-in oven to provide the elevated temperature is not strictly necessary. However, the use of the Joule-effect heating described above may force only a few integrated circuits 2 to fail during the test, and some other integrated circuits 2 could have operating problems in the future that were undetected during the test. Therefore, the manufacturer may decide at which temperature to perform the burn-in test. 
     In addition, by making use of the tristate pad 10 it is possible by means of a test point to extinguish the circuit in such a manner that only the defective circuits absorb electrical power, i.e., those in which there is an internal short circuit. If an integrated circuit is defective or exhibits a failure condition, there is probably a short circuit in it which could connect the connecting conducting line bus 12 connected to the power supply pad 6 with the other connecting conducting line bus 12 connected to the ground pad 8. Depending on the type of failure, current in an integrated circuit 2 with a short circuit could be well in excess of several milliamps, and could be on the order of several amps. However, in accordance with the present invention, this potential danger is avoided by the presence of the resistance R on the connection between the pads 6 and 7 and the connecting conducting line bus 12. The resistance R limits the current passing through the short circuited integrated circuits 2. It has been calculated that current absorption of a defective chip can be about 1 mA if a short circuit occurs in an integrated circuit 2 connected to Vd, with a value of 12 volts, through resistance R with a value of 10 kohm. A short circuit current can be even lower, on the magnitude of 500 μA, if an integrated circuit 2 is connected to Vcc only, and not to Vd. The probability that a failure state might affect the resistance R is much lower than that of a failure of the integrated circuit 2 with which the resistance is associated. Furthermore, the protection diode D in series with the resistance protects the circuit during operation calling for grounding. 
     This protection diode D continues to provide protection even when the integrated circuit 2 has been sectioned from the wafer 1. FIG. 5 shows the metallization strip 13 sectioned vertically following cutting along the scribing line 11. The accessible edge of this metallization strip 13 could constitute an electrical connection path to the substrate. The presence of the protection diode D in the integrated circuit 2 also affords protection against this possible leakage to ground. 
     The present invention also allows drastic reduction of the &#34;infant mortality&#34; phenomenon of circuits already assembled because it is possible to determine failure states subsequent to the so-called zero time. This purpose is attained by stressing the gate oxide of CMOS or DMOS devices incorporated in the integrated circuits 2 with high temperature provided by a burn-in oven. The quality of the DMOS is critical in the thin gate oxide. The CMOS devices can be considered natural tristates since they do not absorb power when they are in an interdiction state. Nevertheless, they exhibit absorption peaks when they go into conduction. 
     In this context the pads 9 and 10 lend themselves effectively to this purpose because it is possible to apply a relatively slow synchronization pulse (clock) on the pad 9 and an enablement signal upon starting on the pad 10. In this manner it is possible to cyclically switch the integrated circuit 2 from the starting state to that of extinguishment for a predetermined period of time, seeking to force a failure state which would have occurred only after a first employment of the circuit. Therefore, the manufacturing method in accordance with the present invention makes possible a burn-in of the wafer by stressing to a failure state all those circuits which would not have had a particularly long useful life. 
     While various embodiments have been described in this application for illustrative purposes, the claims are not so limited. Rather, any equivalent method or device operating according to principles of the invention falls within the scope thereof.