JP6452332B2 - Printed circuit board - Google Patents

Description

  The present invention relates to a printed circuit board having a transmission circuit for transmitting a digital signal and a printed wiring board on which the transmission circuit is mounted.

  In recent years, electronic devices such as digital multi-function peripherals and digital cameras are required to transmit large-capacity digital signals at high speeds in order to demand high speed and high color. In order to transmit these large volumes of data at high speed, it is necessary to increase the number of transmission lines or increase the transmission speed. There is a limit to the number of transmission lines that can be increased in a printed wiring board that is miniaturized and densified. Moreover, when transmitting with a cable, the increase in the number of cable cores directly leads to an increase in cost. Further, as the transmission rate is improved, the timing variation between signals due to skew becomes remarkable, making it difficult to satisfy the setup / hold. Therefore, serial transmission capable of transmitting a large amount of data at high speed with a small number of transmission lines has been widely used.

  The serial transmission system serializes low-speed parallel signals on transmission lines such as data, addresses, and control lines, outputs them differentially, and deserializes the received serial signals to convert them into parallel signals. is there. In this serial transmission method, a clock signal is embedded in a serialized data string for transmission, and the clock and data are reproduced on the receiving side.

  On the other hand, when a high-speed signal is transmitted on a long lossy transmission line such as a cable, part of the signal component is radiated using the cable as an antenna, which may affect the operation of other devices. Therefore, it is necessary to suppress EMI (Electromagnetic interference) from the equipment.

  In the clock embedded serial transmission, data and a synchronous clock are serialized together, and data encoded so that the logic transition rate between the high level and the low level is approximately 50% is transmitted. Therefore, in the serial data to be transmitted, the low level or the high level does not continue for many bits, and a repetitive waveform having a basic period of 1 bit appears dominantly. Therefore, strong EMI from the serial transmission system is observed at an integral multiple of 1-bit period of serial data. The spectrum of data transmitted by a rectangular wave is represented by a sinc function and is known to have no spectrum at a frequency that is an integral multiple of a 1-bit period. That is, EMI occurs at a frequency where there is no spectrum of the transmission signal. For example, when the transmission rate is 1 Gbps, the cycle of 1 bit is 1 GHz (fundamental frequency), and there is no transmission signal spectrum in the integral multiple, but strong EMI occurs. When this clock-embedded serial transmission method is adopted, EMI occurs at a frequency where there is no spectrum of the transmission signal, so it is conceivable to use a band rejection filter or a notch filter for the differential transmission line. The reason is that since the band in the vicinity of the frequency where there is no transmission signal spectrum is cut off, EMI can be cut off positively without affecting the transmission signal.

  Therefore, conventionally, it is known that the band rejection filter has a configuration in which a series circuit of a coil and a capacitor is connected in parallel to the transmission line, or a configuration in which a parallel circuit of the coil and the capacitor is connected in series to the transmission line. (See Non-Patent Document 1). However, in this band rejection filter, the circuit elements are composed of lumped constant elements such as chip parts, so the part constant value is very small in the high frequency region such as the GHz band, and the desired cutoff is required for standard parts. Difficult to get frequency. In addition, it is difficult to obtain a desired cutoff frequency due to variations in component element values.

  A technique for configuring a band rejection filter with a distributed constant circuit is known in order to secure desired characteristics in a high-frequency region and to cope with the problem of variations in element values of components. In a high frequency band such as a GHz band, a distributed constant circuit is generally configured using a pattern formed on a substrate as a distributed constant element. When a distributed constant circuit is composed of distributed constant elements, the element values of lumped constant elements are set by physical dimensions such as the pattern width and line length, and the desired cutoff frequency can be controlled by the dimensions to be formed. Can be easily obtained.

  Conventionally, a band rejection filter composed of distributed constant elements arranges a line related to the electrical length of a frequency to be removed in the vicinity of the main transmission line to remove unnecessary frequency components (Patent Document 1). reference). In Patent Document 1, a line having one end connected to the ground and the other end open is disposed in the vicinity of the transmission line.

  The transmission characteristics of the transmission line configured as described above show that the signal component is attenuated at the fundamental frequency corresponding to λ / 4 (λ: wavelength) and an odd multiple of the electrical length of the line with one end connected to the ground. It becomes like this.

JP-A-9-232804

Risaburo Sato, “Transmission Circuit”, Corona Publishing, June 30, 1963, P277

  However, in Patent Document 1, although there is an EMI removal capability for an odd multiple of the fundamental frequency, attenuation is not obtained for an even multiple frequency, and the EMI removal effect for an even multiple frequency is extremely low. There was a problem. In particular, in clock-embedded serial transmission, a strong spectrum is generated at an integral multiple of the fundamental frequency corresponding to the data transmission rate, and even multiple components cannot be removed.

  Therefore, an object of the present invention is to attenuate the frequency components of an odd multiple and an even multiple of the fundamental frequency corresponding to the data rate of the digital signal with respect to the transmission line.

The printed circuit board of the present invention includes a transmission circuit that transmits a digital signal, and a printed wiring board on which the transmission circuit is mounted. The printed wiring board includes a ground conductor and a digital signal transmitted from the transmission circuit. A transmission line that transmits a signal, and is arranged at a distance from the transmission line along the transmission line, one end of the wiring direction along the transmission line is connected to the ground conductor, and the other end in the wiring direction A coupling line that is electromagnetically coupled to the transmission line, and a central portion in the wiring direction of the coupling line and the ground conductor are connected by a connecting member, and the coupling line the electrical length of the is characterized by a range der Rukoto of the ± 20 [%] with respect to a half wavelength of the frequency at which the transmission circuit corresponds to the data rate of the digital signal to be transmitted.
The printed circuit board of the present invention includes a transmission circuit for transmitting a digital signal and a printed wiring board on which the transmission circuit is mounted. The printed wiring board is transmitted from a ground conductor and the transmission circuit. A transmission line that transmits the digital signal, and the transmission line is disposed so as to be spaced along the transmission line, and one end of the wiring direction along the transmission line is connected to the ground conductor, A coupling line that is electromagnetically coupled to the transmission line, the other end of which is open, and a section between one end of the coupling line and a central portion in the wiring direction of the coupling line, and the coupling In order to generate a standing wave in the section between the other end of the line and the central part of the coupling line in the wiring direction, the central part of the coupling line in the wiring direction and the ground conductor are connected members. Connected And said that you are.

  According to the present invention, it is possible to attenuate the frequency components of odd and even multiples of the fundamental frequency corresponding to the data rate of the digital signal with respect to the digital signal transmitted through the transmission line by the coupling line. Therefore, it is possible to reduce unnecessary electromagnetic noise that is radiated effectively.

It is a figure for demonstrating the printed circuit board which concerns on 1st Embodiment of this invention. It is a graph which shows the result of having calculated the transmission characteristic in the printed wiring board of the printed circuit board concerning a 1st embodiment of the present invention by simulation. It is a top view of the printed circuit board concerning a 2nd embodiment of the present invention. It is a figure for demonstrating the printed circuit board which concerns on 3rd Embodiment of this invention. It is a graph which shows the result of having calculated the transmission characteristic in the printed wiring board of the printed circuit board concerning a 3rd embodiment of the present invention by simulation. It is a graph which shows the relationship between the transmission characteristic with respect to the inductance value of the via conductor in the printed circuit board concerning 3rd Embodiment of this invention, and the length of a coupling line. It is a top view of the printed circuit board concerning a 4th embodiment of the present invention. It is a top view of the printed circuit board concerning a 5th embodiment of the present invention. It is a top view of the printed circuit board concerning a 6th embodiment of the present invention.

  Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

[First Embodiment]
FIG. 1 is a view for explaining a printed circuit board according to the first embodiment of the present invention. 1A is a plan view of a printed circuit board, FIG. 1B is a sectional view of the printed wiring board, FIG. 1C is a circuit diagram showing a circuit configuration of the printed circuit board, and FIG. It is a schematic diagram which shows the mode of the voltage standing wave which generate | occur | produces in a coupling line in the frequency of 1 time, 2 times and 3 times the frequency. A printed circuit board 200 shown in FIG. 1A is mounted on an electronic device (not shown) (for example, an imaging apparatus or an image forming apparatus).

  As shown in FIG. 1A, the printed circuit board 200 includes a printed wiring board 100 and a transmission circuit (signal source) 1 that is mounted on the printed wiring board 100 and is configured by, for example, a semiconductor package. .

  The printed wiring board 100 is a multilayer substrate in which a plurality of conductor layers are laminated via an insulator layer (dielectric layer). In the first embodiment, as shown in FIG. Reference numerals 101 and 102 denote a two-layer substrate (double-sided substrate) laminated via an insulator layer 103. FIG. 1A is a plan view of the printed circuit board 200 viewed from the conductor layer 101 side. The conductor layers 101 and 102 are layers in which conductive conductors are arranged, and the insulator layer 103 is a layer in which insulators (dielectrics) having insulation properties are arranged. Even in the conductor layer, there is an insulator between the conductors, and even in the insulator layer, there is a conductor formed in a via penetrating the insulator. In the first embodiment, since the printed wiring board 100 is a two-layer board, both the conductor layers 101 and 102 are surface layer conductor layers. The transmission circuit 1 is mounted on the conductor layer 101. An insulating film such as a solder resist may be formed on the outer surface of the surface layer.

  As shown in FIG. 1A, the printed wiring board 100 includes a ground conductor 7, a transmission line 3 that transmits a digital signal transmitted from the transmission circuit 1, and a distance from the transmission line 3 along the transmission line 3. And a coupling line 5 that is arranged open and electromagnetically coupled to the transmission line 3.

  In FIG. 1B, the coupling line 5 is disposed on one of the plurality of conductor layers 101 and 102, or the conductor layer 101 in the first embodiment. Therefore, the conductor layer 101 is a conductor layer in which the coupled line 5 is disposed, and the conductor layer 102 is a conductor layer different from the conductor layer 101 in which the coupled line 5 is disposed, that is, a conductor layer adjacent to the conductor layer 101. is there.

  A ground terminal of the transmission circuit 1 is connected to the ground conductor 7. The ground conductor 7 includes a ground pattern (same layer ground pattern of the same layer as the coupled line 5) 71 disposed on the conductor layer 101 and a ground pattern (different layer ground of a layer different from the coupled line 5) disposed on the conductor layer 102. Pattern) 72. In the first embodiment, there are two ground patterns 71, but one or three or more may be used. The ground conductor 7 includes a plurality of ground via conductors 73 that electrically connect the ground pattern 71 and the ground pattern 72. The ground via conductor 73 is a conductor formed in a via (a through hole in the first embodiment) formed in the printed wiring board 100.

  The transmission line 3 is disposed on the conductor layer 101 adjacent to the coupling line 5. In other words, the coupled line 5 is disposed adjacent to the transmission line 3. In the first embodiment, the coupled line 5 is disposed in parallel to the transmission line 3.

  The ground patterns 71 and 71 are disposed so as to surround (pinch) the transmission line 3 and the coupling line 5, and function as a guard ground that reduces electromagnetic radiation leaking from the lines 3 and 5. The ground pattern 72 is disposed at a position overlapping the transmission line 3, the coupled line 5, and the ground pattern 71 when viewed from the direction perpendicular to the surface of the printed wiring board 100 (that is, in FIG. 1A). Since the ground pattern 72 functions as a signal return path, it is preferable that the ground pattern 72 is disposed to face the transmission line 3.

  The transmission line 3 has a start end connected to the transmission circuit 1 and a termination resistor 4 connected to the end. More specifically, the termination resistor 4 is mounted on the conductor layer 101 of the printed wiring board 100, one end is connected to the termination of the transmission line 3, and the other end is connected to the ground pattern 71 of the ground conductor 7. Yes.

  Although not shown, the receiving circuit is connected to the end of the transmission line 3 (one end of the terminating resistor 4) via a wiring pattern of the printed wiring board 100 or a cable connected to the printed wiring board 100 with a connector or the like. ing. That is, the receiving circuit may be mounted on the printed wiring board 100, or may be mounted on another board and connected to the printed wiring board 100 by a cable. Thereby, the receiving circuit can receive the digital signal transmitted from the transmitting circuit 1 and transmitted through the transmission line 3.

  In the coupled line 5, one end 51 in the wiring direction along the transmission line 3 is connected (connected) to the ground pattern 71 of the ground conductor 7, and the other end 53 in the wiring direction is opened. The ground pattern 71 has a surface area larger than that of the coupled line 5. Thereby, the ground potential at each position of the ground pattern 71 is made uniform (impedance reduction), and the grounding effect of the one end portion 51 of the coupled line 5 is enhanced.

  And the center part 52 of the wiring direction of the coupling line 5 and the ground pattern 72 of the ground conductor 7 are connected by the via conductor 6 which is a connection member. The via conductor 6 is a conductor formed in a via (a through hole in the first embodiment) formed in the printed wiring board 100. In FIG. 1C, the resistor 2 is the impedance of the transmission circuit 1.

  Here, the digital signal output from the transmission circuit 1 is a signal that is encoded such that both the data and the synchronous clock are serialized and the logic transition rate between the high level and the low level is approximately 50%. The transmission circuit 1 outputs a single end signal as a digital signal by a single end method.

  Assuming that the frequency corresponding to the data rate of the digital signal is a fundamental frequency, the coupling line 5 is disposed adjacent to the transmission line 3 and is electromagnetically coupled to the transmission line 3. In the signal, frequency components that are integral multiples of the fundamental frequency are attenuated.

  The fundamental frequency can be confirmed by measuring the time waveform of the digital signal with an oscilloscope and calculating the reciprocal (1 / T) of the minimum period (T) of the eye opening when the eye pattern is displayed.

  In the first embodiment, the coupled line 5 is a line (1/2 wavelength line) whose length in the wiring direction is set to ½ wavelength (including tolerance) of the fundamental frequency. Here, in the first embodiment, the line set to ½ wavelength (including tolerance) of the fundamental frequency has a tolerance of about ± 20 [%] with respect to 180 [°] in electrical length. A line, that is, a line having an electrical length in a range of 144 [°] to 216 [°]. That is, the electrical length of the coupled line 5 is in a range of ± 20 [%] with respect to ½ wavelength of the fundamental frequency when the frequency corresponding to the data rate of the digital signal transmitted by the transmission circuit 1 is defined as the fundamental frequency. Is set. If the coupled line 5 is within this range, the frequency component that is an integral multiple of the fundamental frequency can be effectively attenuated in the signal propagating through the transmission line 3.

  As shown in FIG. 1 (d), the coupled line 5 has an open other end 53 that is an antinode of a sine wave voltage, and a center 52 that is grounded to the ground pattern 72 via the via conductor 6. It becomes a node of wave voltage. That is, standing waves V1 and V3 that are odd multiples of a quarter wavelength of the fundamental frequency are generated in a section between the central portion 52 and the other end portion 53 in the coupled line 5. Thereby, the section between the central part 52 and the other end part 53 in the coupled line 5 has a function of attenuating a frequency component that is an odd multiple of the fundamental frequency. In FIG. 1 (d), a ¼ wavelength standing wave V1 generated at the fundamental frequency in the section between the central portion 52 and the other end portion 53 in the coupled line 5 is indicated by a solid line, and is a frequency three times the fundamental frequency. 3/4 standing wave V3 generated in FIG.

  At the same time, the one end portion 51 and the central portion 52 that are grounded to the ground pattern 71 are both antinodes of the sine wave voltage, so that the fundamental frequency of 1 is obtained in the section between the one end portion 51 and the central portion 52 in the coupled line 5. A standing wave V2 having an even multiple of / 4 wavelength is generated. Thereby, the section between the one end portion 51 and the central portion 52 in the coupled line 5 has a function of attenuating a frequency component that is an even multiple of the fundamental frequency. In FIG. 1D, a half-wave standing wave V2 generated at a frequency twice the fundamental frequency in the section between the one end 51 and the center 52 in the coupled line 5 is indicated by a dotted line.

  As described above, the coupled line 5 attenuates the odd frequency and the even frequency of the fundamental frequency corresponding to the data rate of the digital signal passing through the transmission line 3, particularly, the frequency of 1 ×, 2 ×, and 3 ×. give.

  The result of having verified the effect about the printed circuit board 200 shown to Fig.1 (a) demonstrated in 1st Embodiment using the simulator (Ansys Ansdesign Designer) is demonstrated. Hereinafter, a case where the data rate of the digital signal generated by the transmission circuit 1 is 1 [Gbps] and the fundamental frequency corresponding to the data rate is 1 [GHz] will be described.

As a simulation model, the printed wiring board 100 is a double-sided board having a dielectric thickness of 1.6 [mm]. The dielectric was FR4 (relative permittivity 4.3), and the conductor was copper (conductivity 5.8 × 10 ⁷ [S / m]). The transmission line 3 had a length of 120 [mm], a width of 1 [mm], and a thickness of 0.035 [mm]. The coupled line 5 in which the one end 51 is connected to the ground conductor 7 has a length of 82.6 [mm], a width of 1.5 [mm], and a thickness of 0.035 [mm]. The gap between the transmission line 3 and the coupling line 5 was 0.2 [mm]. The central portion 52 of the coupled line 5 is grounded with an inductance of 0.74 [nH] corresponding to a via conductor 6 formed in a via (through hole) having a diameter of 300 [μm] and a length of 1.6 [mm]. Connected to conductor 7.

  In the above configuration, the transmission characteristic S21 of the signal from the start end to the end of the transmission line 3 is calculated so that the degree of noise reduction can be understood. FIG. 2 is a graph showing the result of calculating the transmission characteristic S21 in the printed wiring board 100 by simulation.

  As a result of calculation by simulation, it was −31.68 [dB] at 1 [GHz], −7.57 [dB] at 2 [GHz], and −28.96 [dB] at 3 [GHz]. . It was found to be -6 [dB] or less at the three frequencies of interest, and it was found that noise suppression of more than half was realized.

  As described above, in the first embodiment, the one end portion 51 and the central portion 52 of the coupling line 5 arranged adjacent to the transmission line 3 are connected to the ground conductor 7 and the other end portion 53 is open. Thereby, with respect to the digital signal transmitted through the transmission line 3, it is possible to attenuate the frequency components of odd and even multiples of the fundamental frequency corresponding to the data rate of the digital signal. In particular, it is possible to effectively reduce frequency components that are 1 time, 2 times, and 3 times the fundamental frequency. Thereby, the unnecessary electromagnetic noise radiated | emitted from the cable connected to the transmission line 3 or the transmission line 3 can be reduced effectively.

  Moreover, in the first embodiment, the frequency components of not only odd times but also even times can be reduced with one coupling line 5 with respect to one transmission line 3, so that one transmission line 3 can be used for noise removal. However, it is not necessary to arrange a plurality of stub lines. Therefore, the wiring area of the printed wiring board 100 can be effectively used, or the printed wiring board 100 can be reduced in area (downsized).

[Second Embodiment]
Next, a printed circuit board according to a second embodiment of the present invention will be described. FIG. 3 is a plan view of a printed circuit board according to the second embodiment of the present invention. In the first embodiment, the case where a single-ended signal is transmitted as a digital signal has been described. In the second embodiment, a case where a differential signal is transmitted will be described.

  In recent years, with the speeding up of digital data, a differential transmission method is frequently used for the purpose of reducing EMI and eliminating interference. In the second embodiment, the printed circuit board 200A includes a transmission circuit (signal source) 11 configured to transmit a differential signal as a digital signal, and a printed wiring board 100A. The transmission circuit 11 is mounted on the printed wiring board 100A. The transmission circuit 11 is composed of, for example, a semiconductor package.

  Also in the second embodiment, clock embedded serial transmission is performed as in the first embodiment. The data and the synchronous clock are serialized together, and the encoded data is transmitted so that the logic transition rate between the high level and the low level is approximately 50%.

  The printed wiring board 100A is a multilayer board in which a plurality of conductor layers are laminated via an insulator layer (dielectric layer). In the second embodiment, as in the first embodiment, a case where a two-layer substrate is used will be described as an example. Note that the layer structure of the printed wiring board 100A is the same as in the first embodiment, in which one surface layer is the conductor layer 101, the other surface layer is the conductor layer 102, and the insulator between the conductor layer 101 and the conductor layer 102. The layer will be described as the insulator layer 103.

  The printed wiring board 100A includes a ground conductor 17 and a pair of differential transmission lines 3A and 3B as transmission lines for transmitting a digital signal (differential signal) transmitted from the transmission circuit 11. Further, the printed wiring board 100A is disposed along the differential transmission lines 3A and 3B at a distance from the differential transmission lines 3A and 3B, and is coupled to the differential transmission lines 3A and 3B electromagnetically. Coupling lines 5A and 5B.

  The coupled lines 5A and 5B are arranged on one of the plurality of conductor layers 101 and 102, which is the conductor layer 101 in the second embodiment. Therefore, the conductor layer 101 is a conductor layer in which the coupled lines 5A and 5B are disposed, and the conductor layer 102 is adjacent to a conductor layer different from the conductor layer 101 in which the coupled lines 5A and 5B are disposed, that is, the conductor layer 101. It is a conductor layer.

  The ground conductor 17 has ground patterns (same layer ground patterns in the same layer as the coupled lines 5A and 5B) 71A and 71B arranged on the conductor layer 101. Further, the ground conductor 17 has a ground pattern (different ground pattern of a different layer from the coupled lines 5A and 5B) 172 disposed on the conductor layer 102. The ground conductor 17 includes a plurality of ground via conductors 73A and 73B that electrically connect the ground patterns 71A and 71B and the ground pattern 172. The ground via conductors 73A and 73B are conductors formed in vias (through holes in the second embodiment) formed in the printed wiring board 100A.

  The pair of differential transmission lines 3 </ b> A and 3 </ b> B are disposed on the conductor layer 101 at a distance from each other. The pair of differential transmission lines 3A and 3B must be formed so as to be closely coupled to each other, and are disposed adjacent to each other. In FIG. 3, the pair of differential transmission lines 3A and 3B are arranged in parallel to each other.

  The differential transmission line 3A is disposed adjacent to the coupled line 5A, and the differential transmission line 3B is disposed adjacent to the coupled line 5B. In other words, the coupled line 5A is disposed adjacent to the differential transmission line 3A, and the coupled line 5B is disposed adjacent to the differential transmission line 3B. In the second embodiment, the coupled lines 5A and 5B are arranged in parallel to the differential transmission lines 3A and 3B.

  The pair of ground patterns 71A and 71B are arranged so as to surround (interpose) the differential transmission lines 3A and 3B and the coupled lines 5A and 5B, and reduce electromagnetic radiation leaking from the lines 3A, 3B, 5A, and 5B. It functions as a guard ground. Further, the ground pattern 172 is located at a position overlapping the differential transmission lines 3A and 3B, the coupled lines 5A and 5B, and the ground patterns 71A and 71B when viewed from the direction perpendicular to the surface of the printed wiring board 100A (that is, in FIG. 3). Has been placed.

  The start ends of the pair of differential transmission lines 3A and 3B are connected to the transmission circuit 11, and the termination resistor 14 is connected to the end of the pair of differential transmission lines 3A and 3B. Digital signals having different polarities are transmitted to the differential transmission lines 3A and 3B.

  In addition, although illustration is abbreviate | omitted, a receiving circuit is connected by the connector etc. to the wiring pattern of 100 A of printed wiring boards, or the printed wiring board 100A to the termination | terminus (both ends of termination resistance 14) of a pair of differential transmission lines 3A and 3B. Connected via cable. That is, the receiving circuit may be mounted on the printed wiring board 100A, or may be mounted on another board and connected to the printed wiring board 100A by a cable. Thereby, the receiving circuit can receive the differential signal (digital signal) transmitted from the transmitting circuit 11 and transmitted through the pair of differential transmission lines 3A and 3B.

  In the coupling lines 5A and 5B, one end portions 51A and 51B in the wiring direction along the differential transmission lines 3A and 3B are respectively connected (connected) to the ground patterns 71A and 71B of the ground conductor 17, and the other end in the wiring direction. The parts 53A and 53B are open. The ground patterns 71A and 71B have a surface area larger than that of the coupled lines 5A and 5B. As a result, the ground potential at each position of the ground patterns 71A and 71B is made uniform (impedance reduction), and the grounding effect of the one end portions 51A and 51B of the coupled lines 5A and 5B is enhanced.

  The central portions 52A and 52B in the wiring direction of the coupled lines 5A and 5B are connected to the ground pattern 172 of the ground conductor 17 by via conductors 6A and 6B which are connection members, respectively. The via conductors 6A and 6B are conductors formed in vias (through holes in the second embodiment) formed in the printed wiring board 100A.

  In the second embodiment, the coupled lines 5A and 5B are lines (1/2 wavelength lines) whose length in the wiring direction is set to ½ wavelength (including tolerance) of the fundamental frequency. Here, in the second embodiment, the line set to ½ wavelength (including tolerance) of the fundamental frequency has a tolerance of about ± 20 [%] with respect to 180 [°] in electrical length. A line, that is, a line having an electrical length in a range of 144 [°] to 216 [°]. That is, the electrical lengths of the coupled lines 5A and 5B are ± 20 [%] with respect to ½ wavelength of the fundamental frequency when the frequency corresponding to the data rate of the digital signal transmitted by the transmission circuit 11 is defined as the fundamental frequency. Set to range. If the coupled lines 5A and 5B are within this range, it is possible to effectively attenuate the frequency component that is an integral multiple of the fundamental frequency in the signal propagating through the differential transmission lines 3A and 3B.

  As described above, in the second embodiment, the one end portions 51A and 51B and the central portions 52A and 52B of the coupling lines 5A and 5B arranged adjacent to the differential transmission lines 3A and 3B are connected to the ground conductor 17 and the other end portion. 53A and 53B are open. Thereby, with respect to the digital signal transmitted through the differential transmission lines 3 </ b> A and 3 </ b> B, it is possible to attenuate the frequency components of odd and even multiples of the fundamental frequency corresponding to the data rate of the digital signal. In particular, it is possible to effectively reduce frequency components that are 1 time, 2 times, and 3 times the fundamental frequency. Thereby, the unnecessary electromagnetic noise radiated | emitted from differential transmission line 3A, 3B or the cable connected to differential transmission line 3A, 3B can be reduced effectively.

  Moreover, in the second embodiment, it is possible to reduce not only odd multiples but also even multiple frequency components with one coupled transmission line 5A (5B) with respect to one differential transmission line 3A (3B). Therefore, it is not necessary to arrange a plurality of stub lines for one differential transmission line 3A (3B) for noise removal. Therefore, the wiring area of the printed wiring board 100A can be effectively used, or the printed wiring board 100A can be reduced in area (downsized).

[Third Embodiment]
Next, a printed circuit board according to a third embodiment of the invention will be described. FIG. 4 is a view for explaining a printed circuit board according to the third embodiment of the present invention. 4A is a plan view of the printed circuit board, FIG. 4B is a circuit diagram showing the circuit configuration of the printed circuit board, and FIG. 4C is a frequency that is 1 time, 2 times, and 3 times the fundamental frequency. It is a schematic diagram which shows the mode of the voltage standing wave which generate | occur | produces in a coupling line. Hereinafter, in 3rd Embodiment, about the structure similar to the said 1st Embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted and a different part is demonstrated.

  In the printed wiring board 100B of the printed circuit board 200B of the third embodiment shown in FIG. 4A, instead of the via conductor 6 that is a connecting member of the printed wiring board 100 of the printed circuit board 200 of the first embodiment, The via conductor 36 is used. Other configurations are the same as those in the first embodiment.

  The vias in which the via conductors 36 are formed have a smaller diameter than the vias in which the other via conductors 73 are formed. Therefore, the via conductor 36 has a larger inductance than the other via conductors 73.

  Since one end 51 of the coupled line 5 is directly connected to the ground pattern 71, the inductance is negligible compared to the via conductor 36. Therefore, as shown in FIG. 4B, it can be considered that the central portion 52 of the coupled line 5 is connected to the ground conductor 7 via the inductance element 9 equivalently representing the via conductor 36.

  Similar to the description of FIG. 1D of the first embodiment, FIG. 4C shows a ¼ wavelength standing wave V1 generated at the fundamental frequency by a solid line. Further, a half-wave standing wave V2 generated at a frequency twice the fundamental frequency is indicated by a dotted line. Further, a 3/4 wavelength standing wave V3 generated at a frequency three times the fundamental frequency is indicated by a one-dot chain line.

  Here, due to the inductance element 9, the central portion 52 of the coupled line 5 has a slightly higher impedance than the ground conductor 7 as compared with the case of the first embodiment. As a result, a half-wave standing wave V <b> 2 ′ in which the central portion 52 and the other end portion 53 of the coupled line 5 are antinodes of the sine wave voltage is generated at a frequency twice the fundamental frequency.

  Also in the first embodiment, the half-wave standing wave V2 in which the one end portion 51 and the central portion 52 of the coupled line 5 are both nodes of the sine wave voltage is generated, but only the short-circuited end without the open end. The standing wave generated in this line has a small gain.

  According to the third embodiment, two standing waves V 2 and V 2 ′ having different modes are generated in two sections of the coupled line 5. As a result, it is possible to further reduce noise having a frequency twice as high as the fundamental frequency, which has a small noise reduction effect.

Hereinafter, the result of verifying the effect of the printed circuit board 200B according to the third embodiment of the present invention shown in FIG. 4A using simulation will be described. As a simulation model, the printed wiring board 100B is a double-sided board having a dielectric thickness of 1.6 [mm]. The dielectric was FR4 (relative permittivity 4.3), and the conductor was copper (conductivity 5.8 × 10 ⁷ [S / m]).

  The transmission line 3 had a length of 120 [mm], a width of 1 [mm], and a thickness of 0.035 [mm]. The coupled line 5 having one end 51 connected to the ground conductor 7 has a length of 81.3 [mm], a width of 1.5 [mm], and a thickness of 0.035 [mm]. The gap between the transmission line 3 and the coupling line 5 was 0.2 [mm]. The central portion 52 of the coupled line 5 is connected to the ground conductor 7 by a 1.1 nH inductance element 9 corresponding to a via conductor 36 formed in a via (through hole) having a diameter of 100 [μm] and a length of 1.6 [mm]. Connected.

  In the above configuration, the transmission characteristic S21 of the signal from the start end to the end of the transmission line 3 is calculated so that the degree of noise reduction can be understood. FIG. 5 is a graph showing the result of calculating the transmission characteristic S21 in the printed wiring board 100B by simulation.

  As a result of calculation by simulation, it was −25.38 [dB] at 1 [GHz], −9.96 [dB] at 2 [GHz], and −24.69 [dB] at 3 [GHz]. . It was found to be -6 [dB] or less at the three frequencies of interest, and it was found that noise suppression of more than half was realized.

  Furthermore, by setting the inductance of the inductance element 9 to 1.1 [nH], the attenuation at a frequency twice the fundamental frequency is about 2.5 [dB] as compared with FIG. 2 described in the first embodiment. ] It was found to increase.

  That is, by inserting a via conductor 36 (connection member) having an inductance component between the central portion 52 of the coupled line 5 and the ground conductor 7 and increasing its value, the frequency of twice the fundamental frequency can be obtained. The amount of reduction will increase.

  However, at the same time, since the impedance (reactance) of the via conductor 36 is added to the coupled line 5, the electrical length of the coupled line 5 is extended. As a result, the frequency of the standing wave is shifted to a low frequency. In order to return the resonance frequency shifted by this shift to 1 [GHz], 2 [GHz], and 3 [GHz], the length of the coupled line 5 may be shortened.

Since the impedance Z of the via conductor 36 is proportional to the product of the inductance L and the frequency f as shown in the following equation (1), the degree of influence on the three frequencies is not uniform.
Z∝L * f (1)

  As the value of the inductance of the via conductor 36 is increased in order to increase the amount of frequency reduction that is twice the fundamental frequency, the three resonance frequencies are increased from the desired frequencies 1 [GHz], 2 [GHz], and 3 [GHz]. It will shift.

  FIG. 6 is a graph showing the relationship between the transmission characteristic and the length of the coupled line with respect to the inductance value of the via conductor 36 as a connection member in the printed circuit board according to the third embodiment of the present invention.

  FIG. 6A is a graph showing the transmission amount at each frequency of 1 [GHz], 2 [GHz], and 3 [GHz] with respect to the inductance value of the via conductor 36. It can be seen that if the inductance value of the via conductor 36, which is a connecting member, is in the range of 0.5 [nH] to 3 [nH], noise at three frequencies is simultaneously reduced by more than half.

  FIG. 6B shows a coupled line for simultaneously reducing noise of three frequencies by more than half when the inductance value of the via conductor 36 is varied in the range of 0.5 [nH] to 3 [nH]. The length of 5 is shown. The notation of length is represented by the electrical length when one wavelength in the printed wiring board 100B is 360 [°], and the range of the electrical length of the coupled line 5 is not less than 154 [°] and not more than 170 [°]. .

  In FIG. 6A and FIG. 6B, the inductance value of the via conductor 36 when the fundamental frequency is 1 [GHz] is described. Generalization is possible by normalizing with the fundamental frequency. That is, when normalized by the fundamental frequency and expressed by reactance, it can be expressed as a range of 3.2 [Ω] or more and 18.8 [Ω] or less.

  The case where the connecting member is the via conductor 36 has been described. However, if the connecting member electrically connects the central portion 52 of the coupling line 5 and the ground conductor 7 and has an inductance component, the via conductor 36 is used. It is not limited to. In this case, it is preferable to select a connection member whose reactance due to the inductance component is in the range of 3.2 [Ω] to 18.8 [Ω].

[Fourth Embodiment]
Next, a printed circuit board according to a fourth embodiment of the invention will be described. FIG. 7 is a plan view of a printed circuit board according to the fourth embodiment of the present invention. In the third embodiment, a case where a single-ended signal is transmitted as a digital signal has been described. In the fourth embodiment, a case where a differential signal is transmitted will be described. In FIG. 7, about the structure similar to the said 1st-3rd embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted and a different part is demonstrated.

  In the printed wiring board 100C of the printed circuit board 200C of the fourth embodiment, the via conductors 36A and 36B are used instead of the via conductors 6A and 6B that are connecting members of the printed wiring board 100A of the printed circuit board 200A of the second embodiment. It is what. Other configurations are the same as those of the second embodiment. The via conductors 36A and 36B have the same configuration as the via conductor 36 described in the third embodiment. That is, the via conductors 36A and 36B have a larger inductance than the other via conductors 73A and 73B.

  That is, two standing waves having different modes are generated in two sections in each of the coupled lines 5A and 5B by the inductance components of the via conductors 36A and 36B. As a result, it is possible to further reduce noise having a frequency twice as high as the fundamental frequency, which has a small noise reduction effect.

  Similar to the third embodiment, also in the fourth embodiment, the reactances of the via conductors 36A and 36B are preferably set in a range of 3.2 [Ω] or more and 18.8 [Ω] or less.

  Similarly to the third embodiment, also in the fourth embodiment, it is preferable that the electrical lengths of the coupled lines 5A and 5B be set to 154 [°] or more and 170 [°] or less.

  With the configuration of the fourth embodiment, even in the differential transmission mode, similarly to the third embodiment, the signal removal effect of 1, 2 or 3 times the fundamental frequency unnecessary for digital signal transmission can be obtained. Can be increased.

  Although the case where the connecting members are the via conductors 36A and 36B has been described, the present invention is not limited to the via conductors 36A and 36B. The connecting member only needs to have an inductance component that electrically connects the central portions 52A and 52B of the coupled lines 5A and 5B and the ground conductor 17. In this case, it is preferable to select a connection member whose reactance due to the inductance component is in the range of 3.2 [Ω] to 18.8 [Ω].

[Fifth Embodiment]
Next, a printed circuit board according to a fifth embodiment of the invention will be described. FIG. 8 is a plan view of a printed circuit board according to the fifth embodiment of the present invention. In the first to fourth embodiments, the case where the coupled line is disposed on the same conductor layer as the layer on which the transmission line is disposed has been described. 5th Embodiment demonstrates the case where a coupling line is arrange | positioned in the adjacent conductor layer different from the conductor layer in which the transmission line is arrange | positioned. In FIG. 8, the same components as those in the above embodiment are denoted by the same reference numerals and description thereof is omitted. Hereinafter, a different point from the said embodiment is demonstrated.

  A printed wiring board 100D of the printed circuit board 200D shown in FIG. 8 is a two-layer board (multilayer board) as in the first to third embodiments. One surface layer is the conductor layer 101 and the other surface layer is the other. The conductor layer 102 and the insulator layer are referred to as an insulator layer 103. FIG. 8 shows a plan view of the printed circuit board 200D viewed from the conductor layer 102 side.

  The printed wiring board 100 </ b> D includes a ground conductor 17 </ b> D and a pair of differential transmission lines 3 </ b> A and 3 </ b> B that are transmission lines that transmit a differential signal (digital signal) transmitted from the transmission circuit 11. Further, the printed wiring board 100D is disposed along the differential transmission lines 3A and 3B at a distance from the differential transmission lines 3A and 3B, and is electromagnetically coupled to the pair of differential transmission lines 3A and 3B. A coupling line 15 is provided.

  In the coupling line 15, one end 151 in the wiring direction along the differential transmission lines 3A and 3B is connected to the ground conductor 17D, and the other end 153 in the wiring direction is opened. Here, in FIG. 8, the transmission circuit 11 and the termination resistor 14 are mounted on the back side (conductor layer 101) of the printed wiring board 100D, and a pair of differential transmission lines 3A and 3B are arranged. In FIG. 8, the coupling line 15 is arranged along the differential transmission lines 3 </ b> A and 3 </ b> B on the front side (conductor layer 102) of the printed wiring board 100 </ b> D. The coupling line 15 is disposed on the conductor layer 102, and the pair of differential transmission lines 3 </ b> A and 3 </ b> B are disposed on a conductor layer 101 that is adjacent to the conductor layer 102 on which the coupling line 15 is disposed and is different from the conductor layer 102. Has been.

  The pair of differential transmission lines 3A and 3B are arranged at positions overlapping one coupling line 15 when viewed from a direction perpendicular to the surface of the printed wiring board 100D. In other words, one coupling line 15 is disposed at a position overlapping the pair of differential transmission lines 3A and 3B when viewed from the direction perpendicular to the surface of the printed wiring board 100D. That is, in the fifth embodiment, unlike the second embodiment, one coupling line 15 is arranged for the pair of differential lines 3A and 3B. The coupling line 15 is disposed in parallel to the pair of differential transmission lines 3A and 3B.

  The ground conductor 17D has ground patterns (different layer ground patterns different from the coupling line 15) 171A and 171B arranged on the conductor layer 101. The ground conductor 17D has a ground pattern (same layer ground pattern in the same layer as the coupled line 15) 172D arranged in the conductor layer 102. The ground conductor 17 includes a plurality of ground via conductors 173 that electrically connect the ground patterns 171A and 171B and the ground pattern 172D. The ground via conductor 173 is a conductor formed in a via (through hole in the fifth embodiment) formed in the printed wiring board 100D.

  The ground patterns 171A and 171B are arranged so as to surround (interpose) the differential transmission lines 3A and 3B, and the ground pattern 172D is arranged so as to surround the coupling line 15. Thus, the ground patterns 171A, 171B, and 172D function as guard grounds that reduce electromagnetic radiation leaking from the lines 3A, 3B, and 15.

  In the coupling line 15, one end 151 in the wiring direction along the pair of differential transmission lines 3A and 3B is connected (connected) to the ground pattern 172D of the ground conductor 17D, and the other end 153 in the wiring direction is opened. ing. The ground pattern 172D has a surface area larger than that of the coupled line 15. Thereby, the ground potential is made uniform (impedance reduction) at each position of the ground pattern 172D, and the grounding effect of the one end 151 of the coupled line 15 is enhanced.

  The central portion 152 in the wiring direction of the coupled line 15 and the ground pattern 172D of the ground conductor 17D are connected (connected) by conductor patterns (connection members) 56 and 56 disposed on the conductor layer 102. Although the number of conductor patterns 56 may be one, in the fifth embodiment, since the coupled line 15 is surrounded by the ground pattern 172D, there are two (plural).

  In the fifth embodiment, the coupling line 15 is disposed at a position overlapping the pair of differential transmission lines 3A and 3B when viewed from the direction perpendicular to the surface of the printed wiring board 100D. Therefore, the occupied area becomes smaller than when the transmission line is arranged adjacent to the same layer, and the wiring area of the printed wiring board 100D can be effectively used, or the printed wiring board 100D can be downsized.

  Furthermore, in the fifth embodiment, since one coupling line 15 is arranged corresponding to a pair (a plurality) of transmission lines 3A and 3B, the number of coupling lines corresponding to each of the transmission lines 3A and 3B. The number of coupled lines can be smaller than that of 15. Therefore, the wiring area of the printed wiring board 100D can be effectively used, or the printed wiring board 100D can be further downsized.

  Here, as in the third embodiment, also in the fifth embodiment, the reactance (synthetic reactance) of the conductor pattern 56 as a connecting member is in the range of 3.2 [Ω] to 18.8 [Ω]. It is preferable to set. Similarly to the third embodiment, also in the fifth embodiment, it is preferable that the electrical length of the coupling line 15 is set to 154 [°] or more and 170 [°] or less.

  As described above, even if the differential transmission lines 3A and 3B and the coupling line 15 are arranged in different layers, the basic frequency is 1 time, 2 times unnecessary for digital signal transmission in the differential transmission lines 3A and 3B. Double and triple signals can be removed.

  In the fifth embodiment, the case where the printed wiring board 100D configures a circuit that transmits a differential signal has been described. However, the same applies to a printed wiring board that configures a circuit that transmits a single-ended signal. The transmission line and the coupling line may be arranged in different layers.

  Further, although the case where the connecting member is the conductor pattern 56 has been described, the connecting member may be an inductance element (lumped constant element). Moreover, although the structure which arrange | positioned one coupling line 15 with respect to a pair of differential transmission lines 3A and 3B was demonstrated, you may arrange | position each coupling line with respect to each of a pair of differential transmission lines 3A and 3B. .

  Further, in the case of a multilayer substrate having three or more conductor layers, the coupled line 15 and the ground pattern 172D may be arranged in the inner conductor layer. As a result, the coupled line 15 can be disposed on the inner layer of the substrate, and more components can be mounted on the surface layer.

  Further, a ground pattern may be arranged on another conductor layer. In this case, the central portion 152 of the coupled line 15 and the ground pattern may be connected by a via conductor.

[Sixth Embodiment]
Next, a printed circuit board according to a sixth embodiment of the invention will be described. FIG. 9 is a plan view of a printed circuit board according to the sixth embodiment of the present invention. In the printed circuit board 200E of the sixth embodiment, inductance elements 66A and 66B are used instead of the via conductors 6A and 6B which are connecting members of the printed wiring board 100A of the printed circuit board 200A of the second embodiment. . Therefore, the printed wiring board 100E of the printed circuit board 200E has a configuration in which the via conductors 6A and 6B are omitted from the printed wiring board 100. Other configurations are the same as those of the second embodiment. About the structure similar to the said embodiment, the same code | symbol is attached | subjected and description is abbreviate | omitted. Hereinafter, a different point from the said embodiment is demonstrated.

  In the sixth embodiment, the connection members are inductance elements 66A and 66B mounted on the conductor layer 101 in which the coupled lines 5A and 5B and the ground patterns (same-layer ground patterns) 71A and 71B are arranged. The inductance elements 66A and 66B are lumped constant elements (electric parts) such as coils.

  Similar to the third embodiment, also in the sixth embodiment, it is preferable to set the reactance of the inductance elements 66A and 66B in the range of 3.2 [Ω] or more and 18.8 [Ω] or less. Similarly to the third embodiment, also in the sixth embodiment, it is preferable that the electrical length of the coupled lines 5A and 5B is set to 154 [°] or more and 170 [°] or less.

  As described above, even when the inductance elements 66A and 66B are used as the connection members, signals which are unnecessary for transmission of digital signals on the differential transmission lines 3A and 3B can be removed by 1 time, 2 times or 3 times the fundamental frequency. . As a result, even if the resonance frequency deviates from the design value due to a manufacturing error of the substrate, etc., it is possible to reduce noise at a desired frequency by adjusting the constants of the inductance elements (electric parts) 66A and 66B without recreating the substrate. become.

  In the sixth embodiment, the case where the printed wiring board 100E configures a circuit that transmits a differential signal has been described. However, the same applies to a printed wiring board configured to transmit a single-ended signal. An effect is obtained.

  In the sixth embodiment, the case where the connection members are the inductance elements 66A and 66B has been described. However, as in the fifth embodiment, the connection member may be formed of a conductor pattern.

  The present invention is not limited to the embodiments described above, and many modifications are possible within the technical idea of the present invention.

DESCRIPTION OF SYMBOLS 1 ... Transmission circuit, 3 ... Transmission line, 5 ... Coupling line, 6 ... Via conductor (connection member), 7 ... Ground conductor, 51 ... One end part, 52 ... Center part, 53 ... Other end part, 100 ... Printed wiring board , 200 ... printed circuit board

Claims (17)

A transmission circuit for transmitting a digital signal;
A printed wiring board on which the transmission circuit is mounted,
The printed wiring board is
A ground conductor;
A transmission line for transmitting a digital signal transmitted from the transmission circuit;
The transmission, wherein the transmission line is disposed along the transmission line at a distance from each other, one end of the wiring direction along the transmission line is connected to the ground conductor, and the other end of the wiring direction is opened. A coupling line electromagnetically coupled to the line,
A central portion in the wiring direction of the coupling line and the ground conductor are connected by a connecting member ,
The electrical length of the coupling line is a printed circuit board, wherein the range der Rukoto of the ± 20 [%] with respect to a half wavelength of the frequency at which the transmission circuit corresponds to the data rate of the digital signal to be transmitted.   A transmission circuit for transmitting a digital signal;
  A printed wiring board on which the transmission circuit is mounted,
  The printed wiring board is
  A ground conductor;
  A transmission line for transmitting a digital signal transmitted from the transmission circuit;
  The transmission, wherein the transmission line is disposed along the transmission line at a distance from each other, one end of the wiring direction along the transmission line is connected to the ground conductor, and the other end of the wiring direction is opened. A coupling line electromagnetically coupled to the line,
  Standing waves are generated in a section between one end portion of the coupling line and the central portion in the wiring direction of the coupling line, and in a section between the other end portion of the coupling line and the central portion in the wiring direction of the coupling line. In order to generate each, the printed circuit board is characterized in that a central portion in the wiring direction of the coupling line and the ground conductor are connected by a connecting member. The electrical length of the coupling line is according to claim 2, wherein the transmission circuit is in a range of 1/2 ± 20 [%] with respect to the wavelength of the frequency corresponding to the data rate of the digital signal to be transmitted Printed circuit board. The printed wiring board is a multilayer substrate in which a plurality of conductor layers are laminated via an insulator layer,
The coupling line is disposed in any one of the plurality of conductor layers,
The transmission line, a conductor layer in which the coupling line is disposed, the printed circuit board according to any one of claims 1 to 3, characterized in that it is disposed adjacent to the coupling line. The printed wiring board is a multilayer substrate in which a plurality of conductor layers are laminated via an insulator layer,
The coupling line is disposed in any one of the plurality of conductor layers,
The transmission line is disposed on a conductor layer adjacent to the conductor layer on which the coupling line is disposed, at a position overlapping the coupling line when viewed from a direction perpendicular to the surface of the printed wiring board. The printed circuit board according to any one of claims 1 to 3 . The ground conductor is printed according to claim 4 or 5, characterized in that it has a plurality of different layers ground pattern disposed in different conductor layers and the conductor layer in which the coupling line is disposed within the conductive layer Circuit board. The printed circuit board according to claim 6 , wherein the connection member is a via conductor that connects the heterogeneous ground pattern and a central portion of the coupling line. The ground conductor is disposed in a conductor layer in which the coupling line is disposed, and has the same layer ground pattern connected to one end of the coupling line,
The printed circuit board according to claim 6 or 7 , wherein the same-layer ground pattern and the different-layer ground pattern are connected by a plurality of ground via conductors. The ground conductor is a printed circuit board according to claim 4 or 5, characterized in that it has a same layer ground pattern said coupling line is disposed in the conductive layer is disposed. The connection member is a conductor pattern that is disposed in a conductor layer in which the coupling line and the ground layer ground pattern are disposed, and is a conductor pattern that connects the ground layer pattern and a central portion of the coupling line. 9. A printed circuit board according to 9 . The printed circuit board according to claim 9 , wherein the connection member is an inductance element mounted on a conductor layer in which the coupling line and the ground layer pattern of the same layer are disposed. The one end of the coupling line is, the printed circuit board according to any one of claims 9 to 11, characterized in that connected to the same layer ground pattern. The ground conductor has a different layer ground pattern arranged in a conductor layer different from the conductor layer in which the coupling line and the same layer ground pattern are arranged among the plurality of conductor layers,
Printed circuit board according to any one of claims 9 to 12, characterized in that said said different layer ground pattern and the same layer ground pattern are connected by a plurality of ground via conductors. It said connecting reactance of members, 3.2 [Omega] or more 18.8 [Omega] printed circuit board according to any one of claims 1 to 13, characterized in that less. The printed circuit board according to any one of claims 1 to 14 , wherein an electric length of the coupling line is 154 [°] or more and 170 [°] or less. The transmission circuit is configured to transmit a differential signal as the digital signal;
The printed wiring board, wherein the transmission line, printed circuit board according to any one of claims 1 to 15, characterized in that it has a pair of differential transmission line connected to the transmission circuit. The electronic device provided with the printed circuit board of any one of Claims 1 thru | or 16 .

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