Tape carrier package with two regions having leds that connect upon folding

A tape carrier package is provided with a first region which includes a plurality of input leads for transmitting an input signal between a liquid crystal driver IC chip and a section external to the tape carrier package, and a second region which includes signal transmitting wires for transmitting an input signal among a plurality of the input leads, on one of the surfaces of a tape substrate. Further, in the tape substrate, a folding slit is formed along a boundary between the first region and the second region. The tape substrate is folded into 180 degrees along the folding slit serving as a fold so as to electrically connect a plurality of the input leads and the signal transmitting wires. This arrangement makes it possible to prevent a voltage drop caused by wire resistance.

FIELD OF THE INVENTION
 This invention relates to a tape carrier package (TCP) which supports an
 integrated circuit and transmits a signal between a section external to
 the tape carrier package and the integrated circuit, particularly concerns
 a tape carrier package which supports a liquid crystal driver integrated
 circuit (IC) chip for driving a liquid crystal panel disposed in a liquid
 crystal display device, and which transmits a signal among the liquid
 crystal driver IC, the liquid crystal panel, and the section external to
 the TCP.
 BACKGROUND OF THE INVENTION
 Conventionally, in many cases, a liquid crystal driver IC chip for driving
 a liquid crystal panel has been installed in the liquid crystal panel as a
 tape carrier package, which is one of the packages for a semiconductor
 device. Such a liquid crystal driver IC is installed, for example, in a
 liquid crystal panel module shown in FIG. 22.
 As shown in FIG. 22, a liquid crystal panel 70 is provided with a plurality
 of tape carrier packages 72, each having a liquid crystal driver IC chip
 71. Each tape carrier package 72 includes outer leads (not shown)
 connected to output terminals and the liquid crystal driver IC chip 71
 respectively. The liquid crystal driver IC chip IC 71 is connected with
 the liquid crystal panel 70 via the outer leads for the output terminals
 and is connected with a flexible substrate 73 via the outer leads for the
 input terminals. A signal is transmitted and power is supplied to each of
 the liquid crystal driver IC chips 71 via wires disposed on the flexible
 substrate 73.
 In recent years, because of a growing need for more compact and lightweight
 products in the marketplace, it has been necessary to develop a smaller
 version of a semiconductor device disposed in a liquid crystal panel. In
 order to meet such a demand, Japanese Unexamined Patent Publication No.
 3684/1994(Tokukaihei 6-3684, published on Jan. 14, 1994) discloses a
 liquid crystal driver IC tape carrier package. FIG. 23 shows a
 construction of the liquid crystal driver IC tape carrier package
 disclosed in the above publication.
 The above-mentioned liquid crystal driver IC tape carrier package is
 provided with a liquid crystal driver IC chip 117 at the center,
 input/output signal terminals 111 and 112 which are bilaterally
 symmetrical, and a liquid crystal drive output terminal 115 at the center.
 This construction supplies electricity and transmits various signals (for
 example, controlling signals such as a clock, a start signal, and a
 synchronizing signal) by using wires in the liquid crystal driver IC chip
 117. With this arrangement, it is not necessary to provide a flexible
 substrate for supplying power and transmitting various signals.
 Generally, it has been required that such a liquid crystal panel module be
 still more compact and lightweight at lower cost.
 However, in the construction which supplies power and transmits various
 signals by using the wires of the liquid crystal driver IC chip 117, when
 a number of tape carrier packages are connected, a voltage drop may occur
 especially on power supplying wires due to an increase in the number of
 connected tape carrier packages, resulting in degradation in display
 quality of the liquid crystal panel.
 Here, the power supplying wires, which use the wires of the liquid crystal
 driver IC chip 117, are, for example, those connected to liquid crystal
 driving power source.
 Voltage from the liquid crystal driving power source causes a voltage drop
 due to resistance on the wires of the liquid crystal driver IC chip 117,
 and proper driving conditions are not satisfied, resulting in degradation
 in display quality of the liquid crystal panel. Further, voltage from a
 logic driving power source is also supplied by using the wires inside the
 chip; thus, again, a voltage drop may cause an adverse effect on a logic
 operation. Generally, a liquid crystal panel is normally driven by
 connecting a number of liquid crystal driver IC chips to the liquid
 crystal panel, and the greater is the number of LCD IC chips connected,
 the more serious is the described problem of voltage drop.
 SUMMARY OF THE INVENTION
 An objective of the present invention is to provide a tape carrier package
 which can prevent a voltage drop caused by wire resistance.
 In order to achieve the objective, the tape carrier package of the present
 invention, that supports an integrated circuit and transmits a signal
 between a section external to the tape carrier package and the integrated
 circuit, including: a tape substrate having a first region and a second
 region on one of the surfaces thereof, a plurality of leads which are
 formed in the first region and transmit a signal between the section
 external to the tape carrier package and the integrated circuit, and
 signal transmitting wires which are formed in the second region and
 transmit a signal among a plurality of the leads, is characterized in that
 the tape substrate can be folded into 180 degrees along a boundary so as
 to allow the first region and the second region to oppose each other, and
 a plurality of the leads are electrically connected to the signal
 transmitting wires in a state in which the tape substrate is folded.
 With this arrangement, when the tape substrate is folded into 180 degrees
 so as to overlay the leads onto the signal transmitting wires, along a
 boundary serving as a fold between the first region in which a plurality
 of the leads are formed and the second region in which the signal
 transmitting wires are formed, it is possible to electrically connect the
 leads to the signal transmitting wires by soldering, etc. This arrangement
 makes it possible to transmit input signals and supply power among a
 plurality of the leads by using mainly the signal transmitting wires
 disposed on the tape carrier package (TCP), which have lower wire
 resistance as compared with the wires of the integrated circuit.
 Therefore, it is possible to prevent a voltage drop, that has been caused
 by wire resistance (especially, a power supplying wire) of the integrated
 circuit when a number of TCPs are connected in a conventional
 construction, which uses merely the wires of the integrated circuit for
 transmitting input signals and supplying electricity. For example, this
 arrangement makes it possible to prevent a degradation in display quality
 of a liquid crystal display device. Furthermore, with this arrangement,
 the signal transmitting wires are disposed in a horizontal space of the
 tape substrate, so that this arrangement can have virtually the same
 external dimension as the arrangement without signal transmitting wire.
 Additionally, it is possible to overlay the input leads of the tape
 substrate onto the signal transmitting wires of another tape substrate so
 as to connect the input leads to the signal transmitting wires. In this
 case, a shift tends to occur between the input leads and the signal
 transmitting wires due to an error upon overlaying the tape substrate onto
 the other. Meanwhile, in the above-mentioned arrangement, the input leads
 and the signal transmitting wires are disposed on the same tape substrate
 so as to regulate an error occurring upon overlaying the tape substrate
 (shift upon folding the tape substrate). Consequently, it is possible to
 improve accuracy upon overlaying the input leads onto the signal
 transmitting wires.
 For a fuller understanding of the nature and advantages of the invention,
 reference should be made to the ensuing detailed description taken in
 conjunction with the accompanying drawings.

DESCRIPTION OF THE EMBODIMENTS
 [EMBODIMENT 1]
 Referring to FIGS. 1 through 6, the following explanation describes one
 embodiment of the present invention.
 As shown in FIG. 1, a tape carrier package (hereinafter, referred to as a
 TCP) of the present embodiment is provided with a tape substrate 1 which
 includes a straight-line folding slit 2 disposed along the length. The
 tape substrate 1 can be folded into 180 degrees along the folding slit 2
 serving as a fold. Additionally, FIG. 1 shows a liquid crystal driver IC
 chip 20 disposed in a hollowed portion (not shown) as an integrated
 circuit. As for the tape substrate 1, a highly flexible material is
 favorable in order to fold the TCP into 180 degrees along the folding slit
 2 serving as a fold. For example, a polyimide film is preferably used.
 One surface of the tape substrate 1 is divided into two regions by the
 folding slit 2, and one of the regions (first region) is provided with:
 (a)input leads 3-1 through 3-7 which are extended from the liquid crystal
 driver IC chip 20 to the right and left ends so as to be bilaterally
 symmetrical for inputting input signals I1 through I7 from the section
 external to the TCP to the liquid crystal driver IC chip 20; (b)outputting
 leads 4-1 through 4-n which are extended from the liquid crystal driver IC
 chip 20 to the upper end for outputting output signals Ol through On from
 the liquid crystal driver IC chip 20 to the section external to the TCP;
 and (c) external connection slits 5-1 and 5-2 that are bilaterally
 symmetrical so as to connect the input leads 3-1 through 3-7 to input
 leads of another TCP (not shown). The input leads 3-1 through 3-7 are
 disposed so as to be bilaterally symmetrical for inputting the input
 signals I1 through I7 respectively to the left side and the right side,
 which oppose each other in the liquid crystal driver IC chip 20.
 Meanwhile, the other of the two regions, which are divided by the folding
 slit 2 on one surface of the tape substrate 1 (second region), is provided
 with: (a) signal transmitting wires 6-1 through 6-7 which are made of a
 material such as copper so as to transmit input signals I1 through I7
 between the left-side input leads 3-1 through 3-7 and the right-side input
 leads 3-1 through 3-7; and (b) external connection slits 7-1 and 7-2 which
 are bilaterally symmetrical so as to connect the signal transmitting wires
 6-1 through 6-7 to signal transmitting wires of another TCP (not shown).
 When the tape substrate 1 is folded into 180 degrees along the folding slit
 2 serving as a fold, the signal transmitting wires 6-1 through 6-7 are
 disposed so as to be overlaid to the input leads 3-1 through 3-7 on the
 both ends of the tape substrate 1.
 The external connection slits 5-1 and 5-2 are respectively disposed in the
 vicinity of both ends of the IC chip installing region so that the input
 leads 3-1 through 3-7 are partially exposed. The external connection slits
 7-1 and 7-2 are respectively disposed in the vicinity of both ends of the
 signal transmitting wire region so as to partially expose the signal
 transmitting wires 6-1 through 6-7. Further, when the tape substrate 1 is
 folded into 180 degrees along the folding slit 2 serving as a fold, the
 external connection slits 5-1 and the external connection slit 7-1 are
 overlaid to each other and the external connection slit 5-2 and the
 external connection slit 7-2 are overlaid to each other.
 The liquid crystal driver IC chip 20 is disposed on the back of the surface
 of the tape substrate 1 where the input leads 3-1 through 3-7 and the
 signal transmitting wires 6-1 through 6-7 are formed. The liquid crystal
 driver IC chip 20 is connected with the input leads 3-1 through 3-7 and
 the output leads 4-1 through 4-n via input pads and output pads (not
 shown) which are disposed so as to be bilaterally symmetrical on the
 surface where the input leads 3-1 through 3-7 and the signal transmitting
 wires 6-1 through 6-7 of the tape substrate 1 are formed.
 FIG. 2 shows an example of an arrangement of the liquid crystal driver IC
 chip 20, the input pads, and the output pads. The upper end of the liquid
 crystal driver IC chip 20 is provided with output pads 28 which are
 connected with the output leads 4-1 through 4-n. The right and left ends
 of the liquid crystal driver IC chip 20 are provided with input pads 27
 which are connected with the input leads 3-1 through 3-7. The left-side
 input pads 27 and the right-side input pads 27 are electrically connected
 with each other via inside wires 26, which are disposed in the liquid
 crystal driver IC chip 20 and are made of a material such as aluminum.
 With this arrangement, the input signals I1 through I7 are transmitted
 between the left-side input leads 3-1 through 3-7 and the right-side input
 leads 3-1 through 3-7 via the inside wires 26. Here, the inside wires 26
 of the liquid crystal driver IC chip 20 are provided when required, so
 that it is possible to omit the inside wires 26.
 As described above, the TCP of the present embodiment supports the liquid
 crystal driver IC chip 20 and transmits a signal between the section
 external to the TCP and the liquid crystal driver IC chip 20. One surface
 of the tape substrate 1 is provided with: (a) a plurality of the input
 leads 3-1 through 3-7 for transmitting the input signals I1 through I7
 between the liquid crystal driver IC chip 20 and a liquid crystal driver
 IC chip disposed on another TCP; and (b) the signal transmitting wires 6-1
 through 6-7 for transmitting the input signals I1 through I7 between the
 left-side input leads 3-1 through 3-7 and the right-side input leads 3-1
 through 3-7. In order to electrically connect the input leads 3-1 through
 3-7 and the signal transmitting wires 6-1 through 6-7, the tape substrate
 1 can be folded into 180 degrees along the folding slit 2 serving as a
 fold, which is positioned between the input leads 3-1 through 3-7 and the
 signal transmitting wires 6-1 through 6-7, so as to overlay the input
 leads 3-1 through 3-7 onto the signal transmitting wires 6-1 through 6-7.
 Next, the following explanation describes how to electrically connect the
 input leads 3-1 through 3-7 and the signal transmitting wires 6-1 through
 6-7.
 Firstly, solder resist is applied to a predetermined area (described later)
 of the surface where the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 are formed. And then, the tape
 substrate 1 is folded into 180 degrees along the folding slit 2 serving as
 a fold so that the surface where the input leads 3-1 through 3-7 and the
 signal transmitting wires 6-1 through 6-7 are formed is inside of the tape
 substrate 1.
 This arrangement makes it possible to overlay the input lead 3-1 onto the
 signal transmitting wire 6-1, the input lead 3-2 onto the signal
 transmitting wire 6-2, the input lead 3-3 onto the signal transmitting
 wire 6-3, the input lead 3-4 onto the signal transmitting wire 6-4, the
 input lead 3-5 onto the signal transmitting wire 6-5, the input lead 3-6
 onto the signal transmitting wire 6-6, and the input lead 3-7 onto the
 signal transmitting wire 6-7. Further, the external connection slit 5-1 is
 overlaid to the external connection slit 7-1, and the external connection
 slit 5-2 is overlaid to the external connection slit 7-2.
 Moreover, at a position where the external connection slit 5-1 is overlaid
 to the external connection slit 7-1, and at a position where the external
 connection slit 5-2 is overlaid to the external connection slit 7-2, the
 input leads 3-1 through 3-7 are soldered onto the signal transmitting
 wires 6-1 through 6-7 so as to be electrically connected with one another.
 With this arrangement, the input signals I1 through I7 are transmitted
 between the left-side input leads 3-1 through 3-7 and the right-side input
 leads 3-1 through 3-7 via the signal transmitting wires 6-1 through 6-7.
 Therefore, the left-side input leads 3-1 through 3-7 are connected with
 the right-side input leads 3-1 through 3-7 in parallel via the inside
 wires 26 of the liquid crystal driver IC chip 20 and the signal
 transmitting wires 6-1 through 6-7 disposed on the tape substrate 1. This
 arrangement makes it possible to transmit the input signals I1 through I7
 between the left-side input leads 3-1 through 3-7 and the right-side input
 leads 3-1 through 3-7 by mainly using the signal transmitting wires 6-1
 through 6-7 on the tape substrate 1, that have lower wire resistance as
 compared with the inside wires 26 of the liquid crystal driver IC chip 20.
 Thus, as compared with a construction in which the inside wires 26 or the
 signal transmitting wires 6-1 through 6-7 are used for transmitting input
 signals and supplying power, it is possible to reduce wire resistance and
 to prevent a voltage drop caused by wire resistance.
 FIG. 3 shows one embodiment of a liquid crystal display device, in which
 the liquid crystal driver IC chip 20 is disposed on the TCP of the present
 embodiment and the TCP is mounted on the liquid crystal panel.
 In the above liquid crystal display device, the output leads 4-1 through
 4-n (shown in FIG. 1) of each TCP are connected with a liquid crystal
 panel 30. Further, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 (shown in FIG. 1) are electrically
 connected with one another between the TCPs via the external connection
 slits 5 and 7 (5-1 and 7-1, or 5-2 and 7-2). Thus, the input signals I1
 through I7 (shown in FIG. 1) are transmitted via the signal transmitting
 wires 6-1 through 6-7.
 FIG. 4 shows an A--A sectional view of the liquid crystal driver IC chip 20
 of the liquid crystal display device shown in FIG. 3. Moreover, FIG. 5
 shows a B--B sectional view of the external connection slits 5 and 7 of
 the liquid crystal display device shown in FIG. 3. Additionally, in FIGS.
 4 and 5, materials including a sealing resin and solder are not shown
 because they do not directly relate to the present invention.
 As shown in FIG. 4, in each of the TCPs, in a portion where the liquid
 crystal driver IC chip 20 is mounted, solder resist 8 is applied to a
 predetermined area (described later) inside of the TCP, and the input
 leads 3 (3-1 through 3-7) and the signal transmitting wires 6 (6-1 through
 6-7) are electrically insulated. Meanwhile, as shown in FIG. 5, at
 external connection slits 5 and 7 of each of the TCPs, the input leads 3
 are overlaid onto the signal transmitting wires 6, and the input leads 3
 are electrically connected with the signal transmitting wires 6 by solder
 (not shown).
 Next, referring to FIG. 6, the following explanation describes how to
 connect the TCPs. Here, FIG. 6 is a C--C sectional view of the TCP of the
 liquid crystal display device shown in FIG. 3.
 Firstly, as shown in FIG. 6, a plurality of TCPs are arranged so that the
 external connection slits 5 and 7 are overlaid to each other in each of
 the TCPs. Next, at a portion which is exposed through the external
 connection slits 5 and 7, the input leads 3 and the signal transmitting
 wires 6 of one TCP are electrically connected with the input leads 3 and
 the signal transmitting wires 6 of another TCP via solder 12. With this
 arrangement, the input leads 3-1 through 3-7 and the signal transmitting
 wires 6-1 through 6-7 are electrically connected among a plurality of
 TCPs. Therefore, it is possible to directly transmit the input signals I1
 through I7 among a plurality of TCPs. Consequently, it is not necessary to
 connect a parallel connection substrate, which transmits the input signals
 I1 through I7, to each of the TCPs; thus, a more compact and lightweight
 device can be realized at lower cost.
 [EMBODIMENT 2]
 Referring to FIG. 7, the following explanation describes another embodiment
 of the present invention. Here, for convenience of explanation, those
 members that have the same functions and that are described in the first
 embodiment are indicated by the same reference numerals and the
 description thereof is omitted.
 As shown in FIG. 7, a TCP of the present embodiment is identical to the TCP
 of the first embodiment, except that: input leads 3-1 through 3-14 are
 provided so as to be bilaterally unsymmetrical instead of input leads 3-1
 through 3-7 which are bilaterally symmetrical, and fourteen signal
 transmitting wires 6-1 through 6-14 are provided instead of the seven
 signal transmitting wires 6-1 through 6-7. Additionally, FIG. 7 shows a
 liquid crystal driver IC chip 20 mounted as an integrated circuit in a
 hollowed portion (not shown) of the TCP.
 The TCP of the present embodiment is different from the TCP of the first
 embodiment in the following points: in the TCP of the first embodiment,
 the fourteen input leads 3-1 through 3-7, which input the input signals I1
 through I7 to the liquid crystal driver IC chip 20, are divided by seven
 and extended to the right and left on the liquid crystal driver IC chip
 20. The seven input leads on the external connection slit 5-1 has the same
 arrangement as the other seven on the external connection slit 5-2.
 Meanwhile, in the TCP of the present embodiment, the fourteen input leads
 3-1 through 3-14, which input the input signals I1 through I7 to the
 liquid crystal driver IC chip 20, are divided by seven and extended to the
 right and left on the liquid crystal driver IC chip 20. Further, the input
 leads 3-1 through 3-7 of the external connection slit 5-1 are shifted from
 the input leads 3-8 through 3-14 by a spacing which is half the intervals
 of the input leads 3-1 through 3-7.
 Namely, in the TCP of the first embodiment, the input signals I1 through I7
 are inputted respectively to the right and left on the liquid crystal
 driver IC chip 20; meanwhile, in the TCP of the present embodiment, the
 input signals I1 through I7 and the input signals I8 through I14 are
 respectively inputted to the right and left on the liquid crystal driver
 IC chip 20. As a result, the input signals I1 through I14, which are twice
 as many as those of the first embodiment can be input to the liquid
 crystal driver IC chip 20 by the input leads 3-1 through 3-14 formed at
 the same intervals as those of the first embodiment.
 In the TCP of the first embodiment, the seven signal transmitting wires 6-1
 through 6-7 are disposed for transmitting the input signals I1 through I7
 between the left-side input leads 3-1 through 3-7 and the right-side input
 leads 3-1 through 3-7. On the other hand, the TCP of the present
 embodiment, the fourteen signal transmitting wires 6-1 through 6-14 are
 disposed for inputting the input signals I1 through I14 between the input
 leads 3-1 through 3-14 and the input leads of another TCP (not shown).
 Therefore, the signal transmitting wires 6-1 through 6-14 are formed at
 half intervals of those of the signal transmitting wires 6-1 through 6-7
 of the first embodiment.
 Additionally, as long as the input leads 3-1 through 3-14 of the external
 connection slits 5-1 and 5-2 are bilaterally unsymmetrical, the positions
 of the input pads of the liquid crystal driver IC chip 20 are not
 specified.
 Next, the following explanation describes how to electrically connect the
 input leads 3-1 through 3-14 and the signal transmitting wires 6-1 through
 6-14.
 Firstly, in the TCP, solder resist is applied to a predetermined area
 (described later) of the surface where the input leads 3-1 through 3-14
 and the signal transmitting wires 6-1 through 6-14 are formed. And then,
 the tape substrate 1 is folded into 180 degrees (in half) along the
 folding slit 2 serving as a fold so that the surface where the input leads
 3-1 through 3-14 and the signal transmitting wires 6-1 through 6-14 are
 formed is inside of the tape substrate 1.
 This arrangement makes it possible to overlay the input lead 3-1 onto the
 signal transmitting wire 6-2, the input lead 3-2 onto the signal
 transmitting wire 6-4, the input lead 3-3 onto the signal transmitting
 wire 6-6, the input lead 3-4 onto the signal transmitting wire 6-8, the
 input lead 3-5 onto the signal transmitting wire 6-10, the input lead 3-6
 onto the signal transmitting wire 6-12, the input lead 3-7 onto the signal
 transmitting wire 6-14, the input lead 3-8 onto the signal transmitting
 wire 6-1, the input lead 3-9 onto the signal transmitting wire 6-3, the
 input lead 3-10 onto the signal transmitting wire 6-5, the input lead 3-11
 onto the signal transmitting wire 6-7, the input lead 3-12 onto the signal
 transmitting wire 6-9, the input lead 3-13 onto the signal transmitting
 wire 6-11, and the input lead 3 -14 onto the signal transmitting wire 6
 -13. Further, the external connection slit 5-1 is overlaid onto the
 external connection slit 7-1, and the external connection slit 5-2 is
 overlaid onto the external connection slit 7-2.
 Moreover, at a position where the external connection slit 5-1 is overlaid
 onto the external connection slit 7-1, and at a position where the
 external connection slit 5-2 is overlaid onto the external connection slit
 7-2, the input leads 3-1 through 3-7 are soldered to the signal
 transmitting wires 6-2, 6-4, 6-6, 6-8, 6-10, 6-12, and 6-14 so as to be
 electrically connected with one another. And the input leads 3-8 through
 3-14 are soldered to the signal transmitting wires 6-1, 6-3, 6-5, 6-7,
 6-9, 6-11, and 6-13 so as to be electrically connected with one another.
 This arrangement makes it possible to transmit the input signals I1 through
 I14 among the TCPs by mainly using the signal transmitting wires 6-1
 through 6-14 on the tape substrate 1, that has lower wire resistance as
 compared with the inside wires 26 of the liquid crystal driver IC chip 20.
 Thus, it is possible to reduce wire resistance and to prevent a voltage
 drop caused by wire resistance.
 Here, the TCPs are connected with one another in the same manner as the
 TCPs of the first embodiment.
 [EMBODIMENT 3]
 Referring to FIGS. 8 and 9, the following explanation describes still
 another embodiment of the present invention. Here, for convenience of
 explanation, those members that have the same functions and that are
 described in the aforementioned embodiments are indicated by the same
 reference numerals and the description thereof is omitted.
 As shown in FIG. 8, a TCP of the present embodiment is identical to the TCP
 of the first embodiment, except that instead of a pair of external
 connection slits 5-1 and 5-2 which are bilaterally symmetrical on one of
 the regions which are divided by a folding slit 2, an external connection
 slit 5 is provided and a solder resist nonapplying portion 9 is provided
 so as to be overlaid onto an external connection slit 7-2 of the tape
 substrate 11 and to be bilaterally symmetrical with the external
 connection slit 5. Additionally, FIG. 8 shows a liquid crystal driver IC
 chip 20 mounted as an integrated circuit in a hollowed portion (not shown)
 of the TCP.
 In the TCP of the first embodiment, as shown in FIGS. 4 and 5, at the
 external connection slits 5 and 7 (5-1 and 7-1, or 5-2 and 7-2), the input
 leads 3-1 through 3-7 and the signal transmitting wires 6-1 through 6-7
 are exposed on both surfaces.
 However, according to the TCP of the present invention, the input leads 3-1
 through 3-7 are soldered to the signal transmitting wires 6-1 through 6-7,
 and the input leads 3-1 through 3-7 and the signal transmitting wires 6-1
 through 6-7 are soldered to the input leads and the signal transmitting
 wires of another TCP by holding the substrate in half, it is only required
 that the input leads 3-1 through 3-7 and the signal transmitting wires 6-1
 through 6-7 are exposed to one surface. Namely, even when the surface
 which exposes the input leads 3-1 through 3-7 and the signal transmitting
 wires 6-1 through 6-7 and the other surface have the tape substrates, it
 is possible to fold the tape substrate, to solder the input leads 3-1
 through 3-7 and the signal transmitting wires 6-1 through 6-7, and to
 solder the input leads 3-1 through 3-7 and the signal transmitting wires
 6-1 through 6-7 to the input leads and the signal transmitting wires of
 another TCP.
 Here, in the TCP of the present embodiment, the tape substrate 11 does not
 have the external connection slit 5-2 of the tape substrate 1 of the first
 embodiment. With this arrangement, when the tape substrate 11 is fold into
 180 degrees along a folding slit 2 serving as a fold so as to overlay the
 input leads 3-1 through 3-7 onto the signal transmitting wires 6-1 through
 6-7, the solder resist non-applying portion 9 of the tape substrate 11
 remains in a region opposing the external connection slit 7-2. Hence, as
 shown in FIG. 9, at a portion which is exposed by the external connection
 slit 7 (7-2), the input leads 3 (3-1 through 3-7) and the signal
 transmitting wires 6(6-1 through 6-7) are supported by an area of the tape
 substrate 11 (Namely, a solder resist non-applying portion 9), that
 opposes the external connection slit 7, from the back of the exposed
 surface. As a result, as compared with the TCP of the first embodiment, it
 is possible to reduce occurrence of breaking of wire on the input leads 3
 and the signal transmitting wires 6 at the portion which is exposed by the
 external connection slit 7. Therefore, without increasing the strength of
 the input leads 3 and the signal transmitting wires 6, it is possible to
 prevent breaking of wire upon handling so as to realize easy-to-handle
 leads and wires and to improve reliability of the electrical connection.
 Additionally, in FIG. 9, materials including a sealing resin and solder
 are not shown because they do not directly relate to the present
 invention.
 In the TCPs of Embodiments 1 and 2, on the surface where the input leads
 3-1 through 3-7 and the signal transmitting wires 6-1 through 6-7 are
 formed, solder resist is applied before folding the tape substrate 1, in
 regions other than (a) a portion where output leads 4-1 through 4-n
 (projecting portions of the upper ends shown in FIGS. 1 and 7) are exposed
 for outputting output signals O1 through On, the portion connecting tape
 substrate with a liquid crystal panel, (b) a hollowed portion (not shown)
 disposed for mounting the liquid crystal driver IC chip 20 at a position
 corresponding to the liquid crystal driver IC chip 20 of the tape
 substrate 1, (c) the input leads 3-1 through 3-7 disposed on the external
 connection slits 5-1 and 5-2, and (d) the signal transmitting wires 6-1
 through 6-7 disposed on the external connection slits 7-1 and 7-2.
 Meanwhile, the TCP of the present embodiment, on the surface where the
 input leads 3-1 through 3-7 and the signal transmitting wires 6-1 through
 6-7 are formed, solder resist is applied before folding the tape substrate
 1, in regions other than (a) a portion where output leads 4-1 through 4-n
 (projecting portions of the upper ends shown in FIG. 8) are exposed for
 outputting output signals O1 through On, the portion connecting tape
 substrate with the liquid crystal panel, (b) a hollowed portion(not shown)
 disposed for mounting the liquid crystal driver IC chip 20 at a position
 corresponding to the liquid crystal driver IC chip 20 of the tape
 substrate 11, (c) the input leads 3-1 through 3-7 disposed on the external
 connection slit 5, (d) the signal transmitting wires 6-1 through 6-7
 disposed on the external connection slits 7-1 and 7-2, (e) the solder
 resist non-applying portion 9, and (f) input leads 3-1 through 3-7
 disposed on the solder resist non-applying portion 9.
 It is possible to electrically connect the input leads 3-1 through 3-7 to
 the signal transmitting wires 6-1 through 6-7 in the same manner as the
 first embodiment. Firstly, in the TCP, solder resist is applied to the
 region of the surface where the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 are formed, and then, the tape
 substrate 11 is folded into 180 degrees along the folding slit 2 serving
 as a fold so that the surface where the input leads 3-1 through 3-7 and
 the signal transmitting wires 6-1 through 6-7 are formed is inside of the
 tape substrate 11. Thus, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 overlay each other. Moreover, the
 external connection slits 5 and the external connection slit 7-1 overlay
 each other, and the solder resist non-applying portion 9 and the external
 connection slit 7-2 overlay each other.
 Further, at a position where the external connection slit 5 and the
 external connection slit 7-1 overlay each other, and at a position where
 the solder resist non-applying portion 9 and the external connection slit
 7-2 overlay each other, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 are soldered so as to be electrically
 connected with one another. This arrangement makes it possible to input
 the input signals I1 through I7 by mainly using the signal transmitting
 wires 6-1 through 6-7 of the tape substrate 11, that has lower wire
 resistance as compared with the inside wires 26 of the liquid crystal
 driver IC chip 20. Therefore, it is possible to reduce wire resistance and
 to prevent a voltage drop caused by wire resistance.
 Further, the TCPs are connected with one another as follows: firstly, a
 plurality of TCPs are arranged so as to overlay the external connection
 slit 7-2 of one TCP onto the external connection slits 5 and 7-1 of
 another TCP. Next, at a portion exposed by the external connection slits
 5, 7-1, and 7-2, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 of the TCP are electrically connected
 with the input leads 3-1 through 3-7 and the signal transmitting wires 6-1
 through 6-7 of another TCP by soldering. With this arrangement, the input
 leads 3-1 through 3-7 and the signal transmitting wires 6-1 through 6-7
 are electrically connected among a plurality of TCPs.
 [EMBODIMENT 4]
 Referring to FIG. 10, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 10, a TCP of the present embodiment is identical to the
 TCP of the third embodiment, except that: input leads 3-1 through 3-14 of
 a TCP of the second embodiment are provided so as to be bilaterally
 unsymmetrical instead of bilaterally symmetrical input leads 3-1 through
 3-7, and fourteen signal transmitting wires 6-1 through 6-14 of the second
 embodiment are provided instead of seven signal transmitting wires 6-1
 through 6-7. Additionally, FIG. 10 shows a liquid crystal driver IC chip
 20 mounted in a hollowed portion (not shown) of the TCP as an integrated
 circuit.
 In the TCP of the third embodiment, the input signals I1 through I7 are
 inputted to the right and left of the liquid crystal driver IC chip 20. In
 contrast, according to the TCP of the present embodiment, the input
 signals I1 through I7 and the input signals I8 through I14 are
 respectively inputted to the right and left of the liquid crystal driver
 IC chip 20. As a result, the input signals I1 through I14, which are twice
 as many as those of the third embodiment can be input to the liquid
 crystal driver IC chip 20 by the input leads 3-1 through 3-14 formed at
 the same intervals as those of the first embodiment.
 Additionally, the positions of the input pads of the liquid crystal driver
 IC chip 20 are not particularly specified.
 It is possible to electrically connect the input leads 3-1 through 3-14 to
 the signal transmitting wires 6-1 through 6-14, in the same manner as the
 second embodiment. Firstly, in the same manner as the third embodiment,
 solder resist is applied, and then, a tape substrate 11 is folded into 180
 degrees along a folding slit 2 serving as a fold so that the surface where
 the input leads 3-1 through 3-14 and the signal transmitting wires 6-1
 through 6-14 are formed is inside of the tape substrate 11.
 With this arrangement, the input leads 3-1 through 3-7 are overlaid onto
 the signal transmitting wires 6-2, 6-4, 6-6, 6-8, 6-10, 6-12, and 6-14,
 the input leads 3-8 through 3-14 are overlaid onto the signal transmitting
 wires 6-1, 6-3, 6-5, 6-7, 6-9, 6-11, and 6-13. Further, an external
 connection slit 5 is overlaid onto an external connection slit 7-1, and
 the a solder resist non-applying portion 9 is overlaid onto an external
 connection slit 7-2.
 Moreover, at a position where the external connection slit 5 is overlaid
 onto the external connection slit 7-1, and at a position where the solder
 resist non-applying portion 9 is overlaid onto the external connection
 slit 7-2, the input leads 3-1 through 3-7 are soldered so as to be
 electrically connected to the signal transmitting wires 6-2, 6-4, 6-6,
 6-8, 6-10, 6-12, 6-14; and the input leads 3-8 through 3-14 are soldered
 so as to be electrically connected to the signal transmitting wires 6-1,
 6-3, 6-5, 6-7, 6-9, 6-11, and 6-13.
 With this arrangement, the input signals I1 through I14 are transmitted
 among the TCPs by using mainly the signal transmitting wires 6-1 through
 6-14 of the substrate 11, that has lower wire resistance as compared with
 inside wires 26 of the liquid crystal driver IC chip 20. Therefore, it is
 possible to reduce wire resistance and to prevent a voltage drop caused by
 wire resistance.
 The TCPs are connected with one another in the same manner as the TCPs of
 the third embodiment.
 [EMBODIMENT 5]
 Referring to FIG. 11, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 11, a TCP of the present embodiment is identical to the
 TCP of the first embodiment, except that: an external connection slit 7 is
 provided instead of a pair of external connection slits 7-1 and 7-2 which
 are bilaterally symmetrical, on one of the regions which are divided by a
 folding slit 2 of a tape substrate 21; and a solder resist non-applying
 portion 9' is provided so as to be overlaid onto an external connection
 slit 5-2 of the tape substrate 21 and to be bilaterally symmetrical with
 the external connection slit 7. Additionally, FIG. 11 shows a liquid
 crystal driver IC chip 20 mounted in a hollowed portion (not shown) of the
 TCP as an integrated circuit.
 Here, in the TCP of the present embodiment, the tape substrate 21 does not
 include the external connection slit 7-2 of the tape substrate 1 of the
 first embodiment. With this arrangement, when the tape substrate 21 is
 folded into 180 degrees along a folding slit 2 serving as a fold so as to
 overlay the input leads 3-1 through 3-7 onto the signal transmitting wires
 6-1 through 6-7, at a portion which is exposed by the external connection
 slit 5-2, the input leads 3-1 through 3-7 and the signal transmitting
 wires 6-1 through 6-7 are supported by an area of the tape substrate 21
 (namely, the solder resist non-applying portion 9') that opposes the
 external connection slit 5-2, from the back of the exposed surface. As a
 result, as compared with the TCP of the first embodiment, it is possible
 to reduce breaking of wire on the input leads 3-1 through 3-7 and the
 signal transmitting wires 6-1 through 6-7 at the portion which is exposed
 by the external connection slit 5-2. Therefore, it is possible to prevent
 breaking of wire upon handling so as to realize easy-to-handle leads and
 wires and to improve reliability of the electrical connection.
 In the TCP of the present embodiment, on the surface where the input leads
 3-1 through 3-7 and the signal transmitting wires 6-1 through 6-7 are
 formed, solder resist is applied before folding the tape substrate 21, in
 regions other than a portion where output leads 4-1 through 4-n are
 exposed, a hollowed portion disposed for mounting the liquid crystal
 driver IC chip 20, the input leads 3-1 through 3-7 disposed on the
 external connection slits 5-1 and 5-2, the signal transmitting wires 6-1
 through 6-7 disposed on the external connection slit 7, the solder resist
 non-applying portion 9', and the signal transmitting wires 6-1 through 6-7
 disposed on the solder resist non-applying portion 9'.
 It is possible to electrically connect the input leads 3-1 through 3-7 to
 the signal transmitting wires 6-1 through 6-7 in the same manner as the
 first embodiment. Firstly, in the TCP, solder resist is applied to the
 region of the surface where the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 are formed, and then, the tape
 substrate 21 is folded into 180 degrees along the folding slit 2 serving
 as a fold so that the surface where the input leads 3-1 through 3-7 and
 the signal transmitting wires 6-1 through 6-7 are formed is inside of the
 tape substrate 21. Thus, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 are overlaid with each other. Moreover,
 the external connection slits 5-1 and the external connection slit 7-1 are
 overlaid to each other, and the solder resist non-applying portion 9' and
 the external connection slit 5-2 are overlaid to each other.
 Further, at a position where the external connection slit 5-1 and the
 external connection slit 7 are overlaid to each other, and at a position
 where the solder resist non-applying portion 9' and the external
 connection slit 5-2 are overlaid to each other, the input leads 3-1
 through 3-7 and the signal transmitting wires 6-1 through 6-7 are soldered
 so as to be electrically connected with each other. This arrangement makes
 it possible to input the input signals I1 through I7 by mainly using the
 signal transmitting wires 6-1 through 6-7 of the tape substrate 21, that
 has lower wire resistance as compared with the inside wire 26 of the
 liquid crystal driver IC chip 20. Therefore, it is possible to reduce wire
 resistance and to prevent a voltage drop caused by wire resistance.
 Further, the TCPs are connected with one another as follows: firstly, a
 plurality of TCPs are arranged so as to overlay the external connection
 slit 5-2 of one TCP onto the external connection slits 5-1 and 7 of
 another TCP. Next, at a portion exposed by the external connection slits
 5-1, 5-2, and 7, the input leads 3-1 through 3-7 and the signal
 transmitting wires 6-1 through 6-7 of one TCP are electrically connected
 with the input leads 3-1 through 3-7 and the signal transmitting wires 6-1
 through 6-7 of another TCP by soldering. With this arrangement, the input
 leads 3-1 through 3-7 and the signal transmitting wires 6-1 through 6-7
 are electrically connected among a plurality of TCPs.
 [EMBODIMENT 6]
 Referring to FIG. 12, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 12, a TCP of the present embodiment is identical to the
 TCP of the fifth embodiment, except that: input leads 3-1 through 3-14 of
 the TCP of the second embodiment are provided so as to be bilaterally
 unsymmetrical instead of bilaterally symmetrical input leads 3-1 through
 3-7, and fourteen signal transmitting wires 6-1 through 6-14 of the second
 embodiment are provided instead of seven signal transmitting wires 6-1
 through 6-7. Additionally, FIG. 12 shows a liquid crystal driver IC chip
 20 mounted in a hollowed portion (not shown) of the TCP as an integrated
 circuit.
 In the TCP of the fifth embodiment, the input signals I1 through I7 are
 inputted to the right and left of the liquid crystal driver IC chip 20. In
 contrast, according to the TCP of the present embodiment, the input
 signals I1 through I7 and the input signals I8 through I14 are
 respectively inputted to the right and left of the liquid crystal driver
 IC chip 20. As a result, the input signals I1 through I14, which are twice
 as many as those of the third embodiment can be input to the liquid
 crystal driver IC chip 20 by the input leads 3-1 through 3-14 formed at
 the same intervals as those of the first embodiment. Additionally, the
 positions of the input pads of the liquid crystal driver IC chip 20 are
 not particularly specified.
 It is possible to electrically connect the input leads 3-1 through 3-14 and
 the signal transmitting wires 6-1 through 6-14, in the same manner as the
 second embodiment. Firstly, in the same manner as the fifth embodiment,
 solder resist is applied, and then, a tape substrate 21 is folded into 180
 degrees along a folding slit 2 serving as a fold so that the surface where
 the input leads 3-1 through 3-14 and the signal transmitting wires 6-1
 through 6-14 are formed is inside of the tape substrate 21.
 With this arrangement, the input leads 3-1 through 3-7 are overlaid onto
 the signal transmitting wires 6-2, 6-4, 6-6, 6-8, 6-10, 6-12, and 6-14,
 the input leads 3-8 thorough 3-14 are overlaid onto the signal
 transmitting wires 6-1, 6-3, 6-5, 6-7, 6-9, 6-11, and 6-13. Further, an
 external connection slit 5-1 is overlaid onto an external connection slit
 7, and a solder resist non-applying portion 9' is overlaid onto an
 external connection slit 5-2.
 Moreover, at a position where the external connection slit 5-1 is overlaid
 onto the external connection slit 7, and at a position where the solder
 resist non-applying portion 9' is overlaid onto the external connection
 slit 5-2, the input leads 3-1 through 3-7 are soldered so as to be
 electrically connected to the signal transmitting wires 6-2, 6-4, 6-6,
 6-8, 6-10, 6-12, and 6-14; and the input leads 3-1 through 3-14 are
 soldered so as to be electrically connected to the signal transmitting
 wires 6-1, 6-3, 6-5, 6-7, 6-9, 6-11, and 6-13.
 With this arrangement, the input signals I1 through I14 are transmitted
 among the TCPs by using mainly the signal transmitting wires 6-1 through
 6-14 of the substrate 21, which have lower wire resistance as compared
 with inside wires 26 of the liquid crystal driver IC chip 20. Therefore,
 it is possible to reduce wire resistance and to prevent a voltage drop
 caused by wire resistance.
 The TCPs are connected with one another in the same manner as the TCPs of
 the fifth embodiment.
 Here, in the TCPs of embodiments 3 through 6, the solder resist
 non-applying portions 9 and 9' are disposed on the right ends of the tape
 substrates 11 and 21; however, it is also allowed to dispose the solder
 resist non-applying portions 9 and 9' on the left ends of the tape
 substrates 11 and 21.
 Moreover, it is possible to provide the solder resist non-applying portion
 on each of the right and left ends of the tape substrate. Namely, for
 example, instead of the external connection slit (7-1 or 5-1) which is
 diagonally opposite to the solder resist non-applying portion (9 or 9') in
 embodiments 3 through 6, another solder resist non-applying portion can be
 provided.
 Here, a plurality of solder resist non-applying portions are diagonally
 opposite to one another because, as shown in FIG. 6, the TCPs are
 connected with one another by overlaying the upper surface of the left end
 of one TCP, which is positioned to the right of another TCP, onto the
 bottom surface of the right end of another TCP, which is positioned to the
 left, or by overlaying the bottom surface of the left end of one TCP,
 which is positioned to the right of another TCP, onto the upper surface of
 the right end of a TCP, which is positioned to the left.
 Further, in embodiments 1 through 6, the tape substrates 1, 11, and 21 are
 folded so that the surface where the liquid crystal driver IC chip 20 is
 disposed is outside the tape substrates. However, it is possible to change
 an arrangement for connecting to a liquid crystal panel 30 or a method for
 mounting the liquid crystal driver IC chip 20 on the TCP, so that the tape
 substrates 1, 11, and 21 can be folded so that the surface where the
 liquid crystal driver IC chip 20 is disposed is inside the substrates.
 [EMBODIMENT 7]
 Referring to FIGS. 13 through 16, the following explanation describes still
 another embodiment of the present invention. Here, for convenience of
 explanation, those members that have the same functions and that are
 described in the aforementioned embodiments are indicated by the same
 reference numerals and the description thereof is omitted.
 As shown in FIG. 13, unlike the tape substrate of the first embodiment, a
 TCP of the present embodiment is provided with a tape substrate 31 having
 a chip hole 10 (opening) for inserting a liquid crystal driver IC chip 20.
 The TCP of the present embodiment is identical to the TCP of the first
 embodiment, except that the liquid crystal driver IC chip 20 is mounted on
 the surface where the input leads 3-1 through 3-7 are disposed.
 The chip hole 10 is disposed so as to be overlaid onto the liquid crystal
 driver IC chip 20, when the liquid crystal driver IC chip 20 is mounted
 and the surface where the liquid crystal driver IC chip 20 is mounted is
 folded into 180 degrees along a folding slit 2 serving as a fold.
 As for the tape substrate 1 without the chip hole 10, in the case when the
 liquid crystal driver IC chip 20 is provided on the surface where the
 input leads 3 are disposed and the tape substrate 1 is folded into 180
 degrees so as to allow the surface where the input leads 3 are disposed to
 be inside of the substrate 1, it is not possible to bring the tape
 substrate 1 into intimate contact due to a thickness of the liquid crystal
 driver chip 20.
 In the TCP of the present embodiment, when the tape substrate 31 is folded
 into 180 degrees along the folding slit 2 serving as a fold so that the
 surface where the liquid crystal driver IC chip 20 is mounted is inside of
 the tape substrate 31, as shown in FIG. 14, the liquid crystal driver IC
 chip 20 penetrates the chip hole 10, so that regardless of the thickness
 of the liquid crystal driver chip 20, it is possible to fold the tape
 substrate 31 into 180 degrees so as to bring the tape substrate 31 into
 intimate contact without a gap.
 Therefore, the tape substrate 31 can be folded into a compact substrate.
 Further, it is possible to prevent a gap of the tape substrate 31, that is
 caused by the thickness of the liquid crystal driver IC chip 20, from
 damaging the tape substrate 31, the wires disposed on the substrate 31,
 and an inner lead portion connected with the liquid crystal driver IC chip
 20; consequently, a reliable TCP can be provided. Moreover, as compared
 with the TCP of the first embodiment, it is possible to realize a smaller
 thickness of the TCP upon mounting the liquid crystal driver IC chip 20.
 FIG. 15 shows one embodiment of a liquid crystal display device, in which
 the liquid crystal driver IC chip 20 is mounted on the TCP of the present
 embodiment and the TCP is installed on a liquid crystal panel.
 In the above-mentioned liquid crystal display device, the output leads 4-1
 through 4-n (shown in FIG. 13) of each of the TCPs are connected with a
 liquid crystal panel 30. Further, among the TCPs, the input leads 3-1
 through 3-7 and signal transmitting wires 6-1 through 6-7 (shown in FIG.
 13) are electrically connected with one another via external connection
 slits 5 and 7 (5-1 and 7-1, or 5-2 and 7-2). This arrangement makes it
 possible to transmit input signals I1 through I7 (shown in FIG. 13) via
 the signal transmitting wires 6-1 through 6-7.
 FIG. 16 shows a D--D sectional view of a portion of the liquid crystal
 display device shown in FIG. 15, that includes the liquid crystal driver
 IC chip 20. Here, FIG. 16 does not show materials including a sealing
 resin and solder, which do not directly relate to the present invention.
 As shown in FIG. 16, in a portion where the liquid crystal driver IC chip
 20 is mounted in each of the TCPs, a solder resist 8 is applied to a
 predetermined portion (described later) inside the TCP. The input leads
 3(3-1 through 3-7) and the signal transmitting wires 6 (6-1 through 6-7)
 are electrically insulated. Meanwhile, at the external connection slits 5
 and 7 of each of the TCP, the input leads 3 and the signal transmitting
 wires 6 are overlaid to one another and are electrically connected with
 one another by soldering (not shown).
 Further, in the same manner as the first embodiment, the input leads 3-1
 through 3-7 and the signal transmitting wires 6-1 through 6-7 are
 electrically connected among a plurality of the TCPs. Thus, it is possible
 to directly input the input signals I1 through I7 among a plurality of the
 TCPs. As a result, it is not necessary to connect a parallel connection
 substrate for transmitting the input signals I1 through I7 to each of the
 TCPs; consequently, it is possible to realize a more compact and
 lightweight device at lower cost.
 [EMBODIMENT 8]
 Referring to FIG. 17, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 17, a TCP of the present embodiment is identical to the
 TCP of the second embodiment, except that: the tape substrate 31 of the
 seventh embodiment is provided instead of the tape substrate 1 of the
 second embodiment, and a liquid crystal driver IC chip 20 is mounted on a
 surface where input leads 3-1 through 3-14 are provided. This arrangement
 makes it possible to achieve the same effect as the seventh embodiment.
 [EMBODIMENT 9]
 Referring to FIG. 18, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 18, a TCP of the present embodiment is identical to the
 TCP of the third embodiment, except that: unlike the tape substrate 11 of
 the third embodiment, a tape substrate 41 is provided so as to include a
 chip hole 10 for inserting a liquid crystal driver IC chip 20 and the
 liquid crystal driver IC chip 20 is mounted on a surface where input leads
 3-1 through 3-17 are provided.
 Therefore, regardless of the thickness of the liquid crystal driver chip
 20, it is possible to fold the tape substrate 41 into 180 degrees without
 a gap so that the surface where the liquid crystal driver IC chip 20 is
 mounted is inside the tape substrate 41. Thus, the tape substrate 41 can
 be folded into a compact substrate, and it is possible to prevent a damage
 occurring on the tape substrate 41, the wires on the tape substrate 41,
 and an inner lead portion connected with the liquid crystal driver IC chip
 20. Further, as compared with the TCP of the third embodiment, it is
 possible to realize a smaller thickness of the TCP upon mounting the
 liquid crystal driver IC chip 20.
 [EMBODIMENT 10]
 Referring to FIG. 19, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 19, a TCP of the present embodiment is identical to the
 TCP of the fourth embodiment, except that a tape substrate 41 of the ninth
 embodiment is provided instead of a tape substrate 11 of the fourth
 embodiment and a liquid crystal driver IC chip 20 is mounted on a surface
 where input leads 3-1 through 3-14 are disposed. This arrangement makes it
 possible to achieve the same effect as the ninth embodiment.
 [EMBODIMENT 11]
 Referring to FIG. 20, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 20, a TCP of the present embodiment is identical to the
 TCP of the fifth embodiment, except that: unlike a tape substrate 21 of
 the fifth embodiment, a tape substrate 51 is provided so as to include a
 chip hole 10 for inserting a liquid crystal driver IC chip 20, and the
 liquid crystal driver IC chip 20 is mounted on a surface where input leads
 3-1 through 3-7 are provided.
 Therefore, regardless of the thickness of the liquid crystal driver chip
 20, it is possible to fold the tape substrate 51 into 180 degrees without
 a gap, while the surface, on which the liquid crystal driver IC chip 20 is
 mounted, is allowed to be inside the tape substrate 51. Thus, the tape
 substrate 41 can be folded into a compact substrate, and it is possible to
 prevent a damage occurring on the tape substrate 41, the wires on the tape
 substrate 41, and inner lead portion connected with the liquid crystal
 driver IC chip 20. Further, it is possible to realize a smaller thickness
 of the TCP upon mounting the liquid crystal driver IC chip 20.
 [EMBODIMENT 12]
 Referring to FIG. 21, the following explanation describes still another
 embodiment of the present invention. Here, for convenience of explanation,
 those members that have the same functions and that are described in the
 aforementioned embodiments are indicated by the same reference numerals
 and the description thereof is omitted.
 As shown in FIG. 21, a TCP of the present embodiment is identical to the
 TCP of the sixth embodiment, except that a tape substrate 51 of the
 eleventh embodiment is provided instead of a tape substrate 21 of the
 sixth embodiment, and a liquid crystal driver IC chip 20 is mounted on a
 surface where input leads 3-1 through 3-14 are disposed. This arrangement
 makes it possible to achieve the same effect as the eleventh embodiment.
 Each of the aforementioned embodiments is provided with a folding slit 2.
 However, the TCP of the present invention merely needs to have a
 construction in which the tape substrate can be folded into 180 degrees
 between the input leads and the signal transmitting wires. Therefore, the
 TCP of the present invention is also allowed to include more than one
 folding slits. Furthermore, the TCP of the present invention is also
 allowed to include a perforated portion or a thin portion instead of one
 folding slit 2. Here, the construction including the folding slit has the
 following advantages: the conventional arrangement hardly needs to be
 changed as compared with the construction including a perforated portion
 or a thin portion, and the tape can be processed in a relatively simple
 manner.
 Moreover, in the aforementioned embodiments, the input leads 3 are
 respectively connected with the transmitting wires 6; however, it is also
 allowed to have a construction in which merely some of the input leads 3
 are connected with the signal transmitting wires 6. Further, in the case
 when the liquid crystal driver IC chip 20 is provided with a dummy pad in
 order to connect the liquid crystal driver IC chip 20 to the TCP in a
 stable manner, the wires connected to the dummy pad can be connected with
 the signal transmitting wires 6.
 Further, it has been proved that any one of the following chips can be
 adopted as the liquid crystal IC chip 20: an active-matrix driving liquid
 crystal driver IC chip such as a thin film transistor (TFT) liquid crystal
 driver chip, and a simple matrix driving (duty driving) liquid crystal
 driver IC chip. Furthermore, the aforementioned embodiments described a
 construction in which the liquid crystal driver IC chip 20 is mounted on
 the TCP so as to drive a liquid crystal panel; however, the IC of the
 present invention is not limited to the liquid crystal driver IC chip.
 As described above, a first tape carrier package of the present invention,
 that supports an integrated circuit and transmits a signal between a
 section external to the TCP and the integrated circuit, including: on one
 of the surfaces of a tape substrate, a plurality of leads for transmitting
 a signal between the section external to the TCP and the integrated
 circuit, and signal transmitting wires for transmitting a signal among a
 plurality of the leads (between the adjacent tape carrier packages, or in
 a tape carrier package), is characterized in that the tape substrate can
 be folded into 180 degrees along a straight line serving as a fold between
 the leads and the signal transmitting wires so as to overlay the leads
 onto the signal transmitting wires in order to electrically connect the
 leads to the signal transmitting wires.
 With the above-mentioned arrangement, the tape substrate is folded into 180
 degrees along a straight line serving as a fold between the leads and the
 signal transmitting wires so as to overlay the leads onto the signal
 transmitting wires; thus, the leads can be electrically connected to the
 signal transmitting wires by soldering, etc. This arrangement makes it
 possible to transmit input signals and supply power among a plurality of
 leads by mainly using the signal transmitting wires disposed on the tape
 carrier package, the signal transmitting wires having lower wire
 resistance as compared with the wires of the integrated circuit.
 Therefore, it is possible to prevent a voltage drop, that has been caused
 by wire resistance (especially, a power supplying wire) of the integrated
 circuit when a number of TCPs are connected in a conventional
 construction, which uses merely the wires of the integrated circuit for
 transmitting input signals and supplying power. For example, this
 arrangement makes it possible to prevent a degradation in display quality
 of a liquid crystal display device. Furthermore, with this arrangement,
 the signal transmitting wires are disposed in a horizontal space of the
 tape substrate, so that this arrangement can have virtually the same
 external dimension as the arrangement which has no signal transmitting
 wire.
 Additionally, it is possible to overlay the input leads of the tape
 substrate onto the signal transmitting wires of another tape substrate so
 as to connect the input leads to the signal transmitting wires. In this
 case, a shift tends to occur between the input leads and the signal
 transmitting wires due to an error upon overlaying the tape substrate onto
 the other. Meanwhile, in the above-mentioned arrangement, the input leads
 and the signal transmitting wires are disposed on the same tape substrate
 so as to regulate an error occurring upon overlaying the tape substrate
 (shift upon folding the tape substrate in half). Consequently, it is
 possible to improve accuracy upon overlaying the input leads onto the
 signal transmitting wires.
 With the arrangement of the first tape carrier package, a second tape
 carrier package of the present invention is characterized in that the tape
 substrate is provided with a folding slit disposed along the fold.
 With the above-mentioned arrangement, the folding slit is provided along
 the fold so as to precisely overlay the leads onto the signal transmitting
 wires. Further, upon folding the tape substrate, the tape substrate can be
 brought into intimate contact so as to electrically connect the leads to
 the signal transmitting wires by soldering, etc. in a simple and positive
 manner. Moreover, it is possible to reduce stress applied to the fold of
 the tape substrate so as to prevent a damage of the tape substrate.
 With the arrangement of the first or the second tape carrier package, a
 third tape carrier package of the present invention is characterized in
 that the tape substrate is provided with an external connection slit for
 connecting the leads and the signal transmitting wires with the section
 external to the TCP, the external connection slit being disposed so as to
 partially expose the leads and the signal transmitting wires.
 This arrangement makes it possible to solder the leads and the signal
 transmitting wires that are exposed through the external connection slit,
 thereby electrically connecting the leads and the signal transmitting
 wires in a simpler and more positive manner.
 Further, a plurality of tape carrier packages are arranged so as to overlay
 the external connection slit of the tape carrier package onto the external
 connection slit of another, and then, the leads. and the signal
 transmitting wires, that are exposed through the external connection slit,
 are soldered to the leads and the signal transmitting wires of another
 tape carrier package; consequently, it is possible to electrically connect
 the leads and the signal transmitting wires among the tape carrier
 packages. Therefore, among the tape carrier packages, it is possible to
 directly supply power and transmit signals among the tape carrier
 packages. As a result, it is not necessary to connect a parallel
 connection substrate, which supplies power and transmits signals, to each
 of the tape carrier packages; thus, it is possible to realize a more
 compact and lightweight device including a liquid crystal display device
 and to reduce the cost.
 With the arrangement of the third tape carrier package, a fourth tape
 carrier package of the present invention is characterized in that when the
 tape substrate is folded into 180 degrees along a straight line serving as
 a fold between the leads and the signal transmitting wires so as to
 overlay the leads onto the signal transmitting wires, at least parts of
 the leads and the signal transmitting wires, that are exposed by the
 external connection slit, are supported by a region of the tape substrate
 that opposes the external connection slit.
 With this arrangement, when the tape substrate is folded into 180 degrees
 along a straight line serving as a fold between the leads and the signal
 transmitting wires so as to overlay the leads onto the signal transmitting
 wires, at least parts of the leads and the signal transmitting wires, that
 are exposed by the external connection slit, are supported by a region of
 the tape substrate that opposes the external connection slit. Therefore,
 as compared with a construction in which a region opposing the external
 connection slit serves as an external connection slit having no tape
 substrate, it is possible to regulate breaking of wire on the leads and
 the signal transmitting wires that are exposed by the external connection
 slit. Thus, breaking of wire can be prevented upon handling, so that it is
 possible to realize an easy-to-handle tape substrate and to improve
 reliability of the electrical connection.
 With any one of the arrangements of the first through fourth tape carrier
 packages, a fifth tape carrier package of the present invention is
 characterized in that on the tape substrate, after the integrated circuit
 is mounted, when the tape substrate is folded into 180 degrees along a
 straight line serving as a fold between the leads and the signal
 transmitting wires so as to overlay the leads onto the signal transmitting
 wires, a window portion is provided for inserting the integrated circuit
 at a position overlaid with the integrated circuit.
 Generally, the integrated circuit is provided on the surface where the
 leads are disposed, in the tape substrate. In this structure, when the
 tape substrate is folded so as to allow the surface having the leads to be
 inside of the tape substrate, the integrated circuit is sandwiched between
 the tape substrates; thus, it is not possible to bring the tape substrate
 into intimate contact due to the thickness of the integrated circuit.
 Therefore, with the integrated circuit, the thickness of the entire tape
 carrier package is increased and stress is applied to the tape substrate;
 consequently, a damage may appear on the tape substrate or the wires
 including the leads and the signal transmitting wires and on an inner lead
 portion for connecting the integrated circuit and the wires of the tape
 substrate.
 However, with the above-mentioned arrangement, after the integrated circuit
 is mounted, when the tape substrate is folded into 180 degrees along a
 straight line serving as a fold between the leads and the signal
 transmitting wires so as to overlay the leads onto the signal transmitting
 wires, the window portion inserts the integrated circuit at a position
 which is overlaid with the integrated circuit.
 With this arrangement, after the integrated circuit is mounted on the tape
 substrate surface where the leads are disposed, when the tape substrate is
 folded into 180 degrees along a straight line serving as a fold between
 the leads and the signal transmitting wires so as to overlay the leads
 onto the signal transmitting wires, the integrated circuit is inserted
 into the window portion; therefore, regardless of the thickness of the
 integrated circuit, the tape substrate can be brought into intimate
 contact. Thus, it is possible to further reduce the thickness of the tape
 carrier package upon mounting the integrated circuit, and it is possible
 to prevent a damage occurring on the tape substrate or the wires of the
 tape substrate that include the leads and the signal transmitting wires,
 and on an inner lead portion for connecting the wires and the integrated
 circuit of the tape substrate; consequently, reliability of the electrical
 connection can be improved.
 Further, as compared with the case in which the integrated circuit is
 mounted on the back of the tape substrate surface where the leads are
 disposed, it is possible to further reduce the thickness of the tape
 carrier package upon mounting the integrated circuit.
 The invention being thus described, it will be obvious that the same may be
 varied in many ways. Such variations are not to be regarded as a departure
 from the spirit and scope of the invention, and all such modifications as
 would be obvious to one skilled in the art are intended to be included
 within the scope of the following claims.