JP2022189731A - Wiring board, electronic module, and electronic device - Google Patents

Abstract

To reduce the level of electromagnetic noise.SOLUTION: A flexible printed wiring board 101 includes a signal line 201, a shield member 205, and a branch line 104. The shield member 205 has a main surface 2051. The shield member 205 is arranged so that the main surface 2051 is arranged along the signal line 201. The branch line 104 is electrically connected to the shield member 205. The tip of the branch line 104 is an open end 211 that is opened. The branch line 104 extends in a direction parallel to the main surface of the shield member 205.SELECTED DRAWING: Figure 3

Description

The present invention relates to noise countermeasure technology.

2. Description of the Related Art In recent years, electronic devices such as digital cameras are required to transmit large-capacity digital signals at high speed due to progress in image quality improvement. As the signal speed increases, the level of electromagnetic noise leaking from the signal line tends to increase. When the electromagnetic noise increases, for example, the electromagnetic noise interferes with the circuits included in the electronic device, which may cause the electronic device to malfunction. In response to this problem, Patent Document 1 discloses a flexible printed wiring board that reduces electromagnetic noise by surrounding a signal line with a ground layer and a shield layer that are electrically connected.

JP 2007-335455 A

However, in the flexible printed wiring board, if the signal line is surrounded by the ground layer and the shield layer, the rigidity of the flexible printed wiring board may be increased. Further, in a rigid printed wiring board, if a structure in which a signal line is surrounded by a ground layer and a shield layer is used, the degree of freedom in designing the wiring board may be reduced. Therefore, it is desirable to be able to reduce electromagnetic noise even in a wiring board that does not adopt such a structure.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to reduce the level of electromagnetic noise.

According to one aspect of the present invention, the wiring board includes a signal line, a shield member having a main surface along the signal line, and the shield member electrically connected to the shield member and having an open end. and a branch line extending in a direction parallel to the main surface.

The present invention reduces the level of electromagnetic noise.

1 is a schematic diagram of a camera according to a first embodiment; FIG. 4A is a perspective view of members arranged inside a housing of the camera body according to the first embodiment; FIG. (b) is a schematic diagram showing the configuration of the electronic module according to the first embodiment. 4A is a schematic plan view showing a connection structure between a printed wiring board and a flexible printed wiring board of the imaging unit according to the first embodiment; FIG. (b) is a cross-sectional view of the flexible printed wiring board taken along line IIIB-IIIB shown in (a). 1 is a schematic plan view showing an imaging unit according to a first embodiment; FIG. (a) is a schematic plan view of a connection structure of two connectors according to the first embodiment. (b) is a schematic cross-sectional view of the connection structure of two connectors along line VB-VB of (a). (a) is a schematic diagram showing the distribution of current flowing through the flexible printed wiring board according to the first embodiment. (b) is a schematic diagram showing the distribution of current flowing through the connector according to the first embodiment. (a) is an explanatory diagram of an electronic module of a comparative example. (b) is an explanatory diagram of the electronic module of the first embodiment. (a) is a schematic diagram of a part of a flexible printed wiring board of Modification 1. FIG. (b) is a schematic diagram of a part of the flexible printed wiring board of Modification 2. FIG. (c) is a schematic diagram of a part of the flexible printed wiring board of Modification 3. FIG. (a) is a schematic diagram of a part of a flexible printed wiring board of Modification 4. FIG. (b) is a schematic diagram of a portion of a flexible printed wiring board of modification 5; (a) is a schematic plan view showing a connection structure between a printed wiring board and a flexible printed wiring board of an imaging unit according to a second embodiment. (b) is a cross-sectional view of the flexible printed wiring board taken along line XB-XB shown in (a). (a) is a side view showing a part of the electronic module in the example. (b) is a plan view showing a part of the electronic module in the example. BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows the cross-section of the flexible printed wiring board of an Example.

BEST MODE FOR CARRYING OUT THE 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 schematic diagram of a camera 1000 according to the first embodiment. Camera 1000 is a digital camera such as a digital still camera. The camera 1000 may be a camera integrated with a lens, but in this embodiment it is a single-lens digital camera and includes a camera body 1001 . A camera body 1001, that is, a camera 1000 is an example of an electronic device. A lens barrel 2000 is detachable from the camera body 1001 .

A camera body 1001 includes a housing 1002 including an exterior case. The housing 1002 has a mount 1003 to which the lens barrel 2000 can be attached and detached.

A lens barrel 2000 is an interchangeable lens. The lens barrel 2000 is supported by the lens housing 2001 and the lens housing 2001. With the lens housing 2001 attached to the housing 1002, the lens barrel 2000 forms an optical image on the image sensor 401, which will be described later. a system 2002; The imaging optical system 2002 has a plurality of lenses 2110 and 2120 arranged side by side in the optical axis direction. A ring mount 2003 attached to the mount 1003 is provided in the lens housing 2001 .

The camera body 1001 comprises an electronic module 300 arranged inside a housing 1002 . FIG. 2A is a perspective view of members arranged inside the housing 1002 of the camera body 1001 according to the first embodiment. FIG. 2B is a schematic diagram showing the configuration of the electronic module 300 according to the first embodiment. The configuration of the camera body 1001 will be described in detail below with reference to FIGS. 1, 2(a) and 2(b).

The electronic module 300 has an imaging unit 400 , an image processing unit 500 and a wireless communication unit 600 . The imaging unit 400 and the image processing unit 500 are connected by a flexible printed wiring board 101 so as to enable data communication using digital signals. Also, the image processing unit 500 and the wireless communication unit 600 are connected by a cable 715 so as to enable data transmission in the form of digital signals.

A data signal communicated between the imaging unit 400 and the image processing unit 500 through the flexible printed wiring board 101 is a digital signal with a transmission rate of 1 Gbps or more. The data signal is a digital signal of image data in the first embodiment. A digital signal transmitted via the flexible printed wiring board 101 may be either a single-ended signal or a differential signal, but a differential signal that enables faster transmission than a single-ended signal is preferred. preferable. In the first embodiment, digital signals transmitted from the imaging unit 400 to the image processing unit 500 via the flexible printed wiring board 101 are differential signals.

The imaging unit 400 is a printed circuit board including an image sensor 401, which is an example of an electronic component, and a printed wiring board 402 on which the image sensor 401 is mounted. The printed wiring board 402 is a rigid printed wiring board.

The image sensor 401 is, for example, a CMOS (Complementary Metal Oxide Semiconductor) image sensor or a CCD (Charge Coupled Device) image sensor. The image sensor 401 photoelectrically converts the light imaged by the lens barrel 2000, and outputs an electric signal indicating pixel data of each of a plurality of pixels.

Image processing unit 500 is an example of an electronic unit. The image processing unit 500 is a printed circuit board including an image processing IC 501 and a printed wiring board 502 on which the image processing IC 501 is mounted. The printed wiring board 502 is a rigid printed wiring board.

The image processing IC 501 is, for example, a digital signal processor. The image processing IC 501 has a function of acquiring an electrical signal representing data of each pixel from the image sensor 401 via the flexible printed wiring board 101, correcting the acquired electrical signal, and generating image data. The image processing IC 501 also has a function of acquiring image data from the wireless communication unit 600 and a function of transmitting image data to the wireless communication unit 600 .

The wireless communication unit 600 is a printed circuit board capable of wireless communication with an external device such as a PC or wireless router. The wireless communication unit 600 has a wireless communication IC 601 and a printed wiring board 602 on which the wireless communication IC 601 is mounted. The printed wiring board 602 is a rigid printed wiring board. A printed wiring board 602 has an antenna 603 configured by a conductor pattern or the like.

A wireless communication IC 601 is an IC capable of transmitting and/or receiving data to and from an external device via an antenna 603 . For example, the wireless communication IC 601 modulates a digital signal representing image data and transmits it from the antenna 603 as radio waves at a communication frequency of a wireless communication standard. Also, for example, the wireless communication IC 601 demodulates radio waves received by the antenna 603 into digital signals representing image data. The communication frequency is a frequency between 700 MHz and 66 GHz, such as a frequency in the 2.4 GHz band or the 5 GHz band.

A wireless communication unit 600, that is, a wireless communication IC 601, is configured to wirelessly communicate with an external device in compliance with a wireless communication standard. The wireless communication standard is, for example, the WiFi (registered trademark) standard or the Bluetooth (registered trademark) standard, which is the WiFi (registered trademark) standard in this embodiment.

A connector 403 is mounted on the printed wiring board 402 of the imaging unit 400 . The connector 403 is electrically connected to the image sensor 401 through wiring patterns such as signal lines 411 and ground lines 412 formed on the printed wiring board 402 . The printed wiring board 402 also has a ground pattern 413 formed on the surface on which the connector 403 is mounted, that is, on the surface layer which is a conductor layer. Ground pattern 413 is electrically connected to ground line 412 . Ground pattern 413 may be integral with ground line 412 .

A connector 503 is mounted on the printed wiring board 502 of the image processing unit 500 . The connector 503 is electrically connected to the image processing IC 501 through wiring patterns such as signal lines 511 and ground lines 512 formed on the printed wiring board 502 .

Flexible printed wiring board 101 is flexible and arranged in a bent state inside housing 1002 . In addition, in FIG.2(b), the state which extended the flexible printed wiring board 101 straight is illustrated typically. A connector 102 is provided at one of the two ends in the wiring direction, which is the longitudinal direction of the flexible printed wiring board 101 . A connector 103 is provided at the other of the two longitudinal ends of the flexible printed wiring board 101 . Connector 102 is attached to connector 403 . Connector 103 is attached to connector 503 . In this way, the connectors 102 and 403 are connected together, and the connectors 103 and 503 are connected together. As a result, the image sensor 401 of the imaging unit 400 and the image processing IC 501 of the image processing unit 500 are connected through the flexible printed wiring board 101 so as to be able to communicate with each other.

A metal frame 750 is arranged inside the housing 1002 . Image processing unit 500 is fixed to metal frame 750 via metal member 760 . That is, the ground of the printed wiring board 502 of the image processing unit 500 is grounded to the metal frame 750 .

Also, the metal frame 750 is provided with a plurality of coils 700 that are an example of a driving device that mechanically drives the imaging unit 400 . The imaging unit 400 is fixed to the metal member 730 shown in FIG. Metal member 730 and metal frame 750 are electrically connected via a plurality of coils 700 . That is, the ground of the printed wiring board 402 is grounded to the metal frame 750 .

Each coil 700 generates a Lorentz force to drive the imaging unit 400 with respect to the metal frame 750 in the direction opposite to the direction of camera shake. By driving the imaging unit 400 with the plurality of coils 700, a function of correcting camera shake is realized. Therefore, flexible printed wiring board 101 preferably has flexibility.

FIG. 3A is a schematic plan view showing the connection structure between the printed wiring board 402 and the flexible printed wiring board 101 of the imaging unit 400 according to the first embodiment. FIG. 3(b) is a cross-sectional view of flexible printed wiring board 101 taken along line IIIB-IIIB shown in FIG. 3(a). FIG. 4 is a schematic plan view showing the imaging unit 400 according to the first embodiment.

The flexible printed wiring board 101 is a flexible printed wiring board including at least two conductor layers, a conductor layer 251 in the first embodiment, and a conductor layer 252 spaced apart from the conductor layers 251 in the Z direction. Flexible printed wiring board 101 has insulating member 212 and shield member 205 held by insulating member 212 . The shield member 205 is a conductor arranged on the conductor layer 251 and is composed of a conductor pattern. The conductor pattern forming shield member 205 extends in the X direction, which is the longitudinal direction of flexible printed wiring board 101 , and the Y direction, which is the lateral direction of flexible printed wiring board 101 . The X direction and the Y direction are directions orthogonal to the Z direction, and are also directions parallel to the main surface 2051 of the shield member 205 . The Z direction is also the direction perpendicular to the major surface 2051 of the shield member 205 . The shield member 205 is intended to shield against electromagnetic noise, and is composed of a solid or mesh conductor pattern.

A flexible printed wiring board 101 has a signal line 201 and a ground line 202 held by an insulating member 212 . Each of the signal line 201 and the ground line 202 is composed of a conductor. Each of the signal line 201 and the ground line 202 is a strip-shaped conductor pattern having a predetermined width and a predetermined thickness and extending in the X direction, which is the longitudinal direction. The width of the ground line 202 is preferably wider than the width of the signal line 201 .

The plurality of signal lines 201 are arranged on the same conductor layer 252 and arranged side by side at intervals in the Y direction, which is the width direction of the flexible printed wiring board 101 . The ground line 202 is arranged on the conductor layer 252 on which the signal line 201 is arranged. The ground lines 202 are arranged side by side with the signal lines 201 in the Y direction. The signal line 201 and the ground line 202 overlap the shield member 205 when viewed in the Z direction perpendicular to the main surface 2051 of the shield member 205 . That is, the signal line 201 and the ground line 202 are arranged along the main surface 2051 of the shield member 205 . In other words, the shield member 205 is arranged to face the signal line 201 and the ground line 202 via the insulating member 212 so that the main surface 2051 is along the signal line 201 and the ground line 202 . Thus, the signal line 201 and the ground line 202 are arranged to face the main surface 2051 of the shield member 205 with the insulating member 212 interposed therebetween.

The ground line 202 arranged on the conductor layer 252 and the shield member 205 arranged on the conductor layer 251 are electrically connected by vias 206 .

A connector 102 mounted on a flexible printed wiring board 101 has a pin 203 connected to a signal line 201 and a pin 204 connected to a ground line 202 . A connector 403 mounted on a printed wiring board 402 has a pin 208 connected to a signal line 411 and a pin 210 connected to a ground line 412 .

FIG. 5(a) is a schematic plan view of the connection structure of the two connectors 102 and 403 in which the two connectors 102 and 403 are connected to each other according to the first embodiment. FIG. 5(b) is a schematic cross-sectional view of the connection structure of the two connectors 102 and 403 along line VB--VB in FIG. 5(a). By connecting the connector 102 to the connector 403 , the pins 203 and 208 are brought into contact with each other to electrically connect the signal lines 201 and 411 , and the pins 204 and 210 are brought into contact with the ground line 202 . and the ground line 412 are electrically connected.

By the way, when common mode noise is superimposed on the signal inside the image sensor 401, a common mode current propagating in the same direction is generated in the signal line and the ground line in the flexible printed wiring board. Then, when the common mode current propagates through the signal line and the ground line, electromagnetic noise is radiated from the flexible printed wiring board due to the common mode current. Electromagnetic noise is also called radiation noise.

Accordingly, flexible printed wiring board 101 of the first embodiment includes branch line 104 electrically connected to shield member 205 in order to suppress common mode current from propagating from connector 102 to connector 103 . The tip of the branch line 104 is an open end 211 . The branch line 104 is not formed across a plurality of conductor layers, but is a conductor pattern formed in one conductor layer, which is the conductor layer 251 in the first embodiment. That is, the branch line 104 is a conductor pattern formed so as to extend in the X direction and/or the Y direction parallel to the main surface 2051 of the shield member 205 . In the first embodiment, the branch line 104 is a strip-shaped conductor pattern. Since the level of conduction noise, which is a common mode current propagating through flexible printed wiring board 101, is reduced, the level of electromagnetic noise radiated from flexible printed wiring board 101 is reduced.

The mechanism by which the level of electromagnetic noise emitted from flexible printed wiring board 101 is reduced will be described below. FIG. 6A is a schematic diagram showing distribution of current flowing through the flexible printed wiring board 101 according to the first embodiment. FIG. 6B is a schematic diagram showing the distribution of currents flowing through the connector 102 according to the first embodiment. FIG. 6(a) shows the current distribution in the cross section of the flexible printed wiring board 101 along line IIIB-IIIB in FIG. 3(a). FIG. 6(b) shows the current distribution in the cross section of the connector 102 along line VIB--VIB in FIG. 5(b).

As shown in FIG. 6A, in the flexible printed wiring board 101, a common mode current 651 flows in the same direction through the signal line 201 and the ground line 202. As shown in FIG. When the shield member 205 is provided, a return path for the common mode current 651 is formed in the shield member 205 and the return current 652 flows through the shield member 205 . This reduces electromagnetic noise. On the other hand, as shown in FIG. 6B, in connector 102, common mode current 651 flows through pins 203 and 204, but no return path is formed.

Here, the difference in the paths of common mode currents depending on the presence or absence of the branch line 104 will be described. FIG. 7A is an explanatory diagram of an electronic module 300X of a comparative example. FIG. 7B is an explanatory diagram of the electronic module 300 of the first embodiment. The flexible printed wiring board 101X of the electronic module 300X of the comparative example has the same configuration as the flexible printed wiring board 101 of the first embodiment except that the branch line 104 is not provided.

The printed wiring board 402 is the signal transmitting side, and the printed wiring board 502 is the signal receiving side. The grounds of the flexible printed wiring boards 101 and 101X, the shield member 205 and the grounds of the printed wiring boards 402 and 502 are electrically connected to the metal frame 750 . As shown in FIG. 7A, in the electronic module 300X of the comparative example, since the connector 102 does not form a return path, potential fluctuation occurs between the shield member 205 and the ground pattern 413 of the printed wiring board 402. FIG. Due to this potential fluctuation, part of the common mode current propagates through the surface 2052 of the shield member 205 opposite to the principal surface 2051 and forms a loop path LX that propagates to the metal frame 750 . Hereinafter, the common mode current generated in the shield member 205 is also referred to as noise current.

In contrast, the flexible printed wiring board 101 of the first embodiment has branch lines 104 . The spatial impedance is high at the open end 211 of the branch line 104 , and the spatial impedance is low at the connection portion between the branch line 104 and the shield member 205 . Therefore, as shown in FIG. 7B, part of the common mode current generated in the connector 102 and flowing through the shield member 205 flows into the branch line 104 . Then, due to the strength of the electric field at the open end 211, the capacitive coupling between the branch line 104 and the ground pattern 413 of the printed wiring board 402 causes the common mode current flowing in the branch line 104 to flow from the branch line 104 to the ground pattern 413. flow. The common mode current that has flowed through ground pattern 413 returns to connector 102 . Thus, in the first embodiment, the common mode current follows the loop path L1 that is shorter than the loop path LX of the comparative example. Loop path L<b>1 does not include metal frame 750 and includes a portion shorter than the entire length of shield member 205 in the longitudinal direction, branch line 104 , and ground pattern 413 . As a result, the noise current propagating through the shield member 205 of the flexible printed wiring board 101, that is, the noise current reaching the connector 103 is reduced, so that the level of electromagnetic noise emitted from the flexible printed wiring board 101 is reduced. Furthermore, since the noise current flowing through and diffusing the metal frame 750 is reduced, the level of electromagnetic noise radiated from the flexible printed wiring board 101 and the metal frame 750 is reduced. Since the level of electromagnetic noise radiated from flexible printed wiring board 101 and metal frame 750 is reduced, the level of electromagnetic noise received by wireless communication unit 600 is reduced, and stable wireless communication is ensured in wireless communication unit 600. can be done. For example, in the wireless communication unit 600, it is possible to prevent the wireless communication from stopping due to electromagnetic noise and the wireless communication speed from being extremely lowered.

As shown in FIG. 3B, the branch line 104 is fixed to the insulating member 212 by being covered with the insulating member 212 . The branch line 104 is thereby held by the insulating member 212 .

Also, the ground lines 202 are arranged side by side with the signal lines 201 in the Y direction. That is, the ground line 202 is arranged on the conductor layer 252 on which the signal line 201 is arranged. Therefore, compared to a flexible printed wiring board having conductor layers 251 and 252 and a conductor layer different from the conductor layers 251 and 252, and the other conductor layer as a whole being a ground layer, the flexible printed wiring board 101 flexibility. Even with such a configuration, the branch line 104 can effectively reduce the level of electromagnetic noise.

In the first embodiment, branch line 104 branches off from shield member 205 . That is, the branch line 104 is a conductor pattern formed to protrude from one side of the shield member 205 extending in the longitudinal direction (X direction), that is, a protrusion. Therefore, the noise current propagating through the shield member 205 can be more effectively returned to the connector 102, which is the source of the noise current, and the electromagnetic noise radiated from the flexible printed wiring board 101 can be more effectively reduced. can.

Here, as shown in FIG. 2B, the signal line 201 includes two ends 2011 and 2012 in the X direction, which is the wiring direction. End 2011 is the first end on the transmission side of the signal. End 2012 is the second end for receiving signals. In the first embodiment, the end 2011 is the end connected to the imaging unit 400 via the connector 102 and the end 2012 is the end connected to the image processing unit 500 via the connector 103 . Branch line 104 is preferably positioned closer to end 2011 than to end 2012 . As a result, the path length along which the noise current propagates in the flexible printed wiring board 101 can be shortened, and the electromagnetic noise radiated from the flexible printed wiring board 101 can be reduced more effectively.

Further, as shown in FIG. 3A, the branch line 104 is wired such that the open end 211, which is the tip, faces the side of the two ends 2011 and 2012 where the end 2011 is located. That is, the branch line 104 is wired facing the side where the connector 102 is located. This makes it easier for the noise current to return toward the source of the noise current in the branch line 104, and the electromagnetic noise radiated from the flexible printed wiring board 101 can be more effectively reduced.

Moreover, in the first embodiment, the branch line 104 is formed in an L shape. As a result, a portion 1041 including the open end 211 of the branch line 104 extends in the X direction along the signal line 201 . In the first embodiment, the portion 1041 is a portion extending linearly parallel to the signal line 201 . Thereby, the width of the flexible printed wiring board 101 in the Y direction can be reduced. The shape of the branch line 104 is not limited to the L shape, and may be a shape including a curved portion.

At least part of the branch line 104 preferably overlaps the printed wiring board 402 when viewed in a direction perpendicular to the main surface 4021 of the printed wiring board 402, which is the Z direction in the case of FIG. . That is, it is preferable that at least part of the branch line 104 faces the main surface 4021 of the printed wiring board 402 in the Z direction of FIG. Here, the Z direction shown in FIG. 3A is also the direction perpendicular to the main surface 4021 of the printed wiring board 402 .

At least a portion of the branch line 104 may be the entire branch line 104, but is a portion 1042 of the branch line 104 in the first embodiment. In particular, the portion 1042 preferably overlaps the ground pattern 413 of the printed wiring board 402 when viewed in the Z direction of FIG. 3(a). This facilitates capacitive coupling between the branch line 104 and the ground pattern 413 of the printed wiring board 402, thereby more effectively reducing electromagnetic noise.

Portion 1042 preferably includes open end 211 which is the tip of branch line 104 . This makes it easier for the branch line 104 to be capacitively coupled with the ground pattern 413 of the printed wiring board 402, thereby more effectively reducing electromagnetic noise.

The part 1042 is preferably half or more the length L of the branch line 104 . Here, the length L of the branch line 104 is the length in the extending direction of the branch line 104 and is the length of the line segment passing through the center of the branch line 104 in the width direction. The electric field level in the branch line 104 is maximized at the open end 211, gradually decreases from the open end 211 toward the connecting portion between the branch line 104 and the shield member 205, and becomes 0 at the connecting portion. Therefore, if the portion 1042 is half or more the length L of the branch line 104 , it is equivalent to making the entire branch line 104 face the ground pattern 413 . As a result, branch line 104 and ground pattern 413 are effectively capacitively coupled, noise current can be effectively fed back from branch line 104 to connector 102, and electromagnetic noise can be effectively reduced. From this point of view, it is preferable that the entire branch line 104 overlaps the ground pattern 413 when viewed in the Z direction perpendicular to the main surface 4021 of the printed wiring board 402 . It is preferable that the open end 211 of the branch line 104 overlaps the main surface 4021 of the printed wiring board 402 when viewed in the Z direction, but it does not have to overlap.

Here, the length L of the branch line 104, that is, the length L from the open end 211 to the connection portion between the branch line 104 and the shield member 205 is determined by the following formula (1). In equation (1), f is the frequency, c is the speed of light, and _εr is the effective dielectric constant. In equation (1), frequency f is the frequency used for wireless communication in wireless communication unit 600, and is within the range of 700 MHz or more and 66 GHz or less. The speed of light c is approximately 300,000 Km/s. The effective dielectric constant ∈ _r is determined by the dielectric constant of the insulating member 212 and the distance between the shield member 205 and the metal frame 750 .

By setting the length L of the branch line to Equation (1) above, the length L of the branch line 104 can be matched with the target frequency f of the electromagnetic noise to be reduced. Therefore, the level of electromagnetic noise can be further reduced at frequency f. Note that the length L of the branch line with respect to the frequency f may deviate from the value obtained by the formula (1) as long as it is within ±10% of the value obtained by the formula (1).

The frequency f is preferably a frequency included in the 2.4 GHz band or the 5 GHz band. The 2.4 GHz band is a frequency band of 2.4 GHz or more and less than 2.5 GHz, and the 5 GHz band is a frequency band of 5 GHz or more and less than 6 GHz. Both the 2.4 GHz band and the 5 GHz band are frequency bands used in WiFi (registered trademark).

[Modification]
FIG. 8A is a schematic diagram of a part of the flexible printed wiring board of Modification 1. FIG. As shown in FIG. 8(a), the branch line 104A may be linear. At that time, the branch line 104A may be connected to one side of the shield member 205 while being inclined.

FIG. 8B is a schematic diagram of a part of the flexible printed wiring board of Modification 2. FIG. As shown in FIG. 8(b), the branch line 104B may be linear. At that time, the branch line 104B may be connected at right angles to one side of the shield member 205 .

FIG. 8C is a schematic diagram of a part of the flexible printed wiring board of Modification 3. FIG. As shown in FIG. 8(c), the open end 211C of the branch line 104C may face in the opposite direction to the branch line 104 in FIG. 3(a). Although each of the branch lines 104 and 104C has only one bent portion that is bent at an angle of 90 degrees, the present invention is not limited to this. For example, branch lines 104 and 104C may each have two folds in the shape of a 45 degree angle fold. Also, the bent portion may have an arc-shaped radius R.

FIG. 9A is a schematic diagram of a part of the flexible printed wiring board of Modification 4. FIG. As shown in FIG. 9A, the flexible printed wiring board of Modification 4 may include a plurality of branch lines 104 and 104D having different wiring lengths. In Modified Example 4, the target frequency f of the electromagnetic noise to be reduced can be a plurality of different frequencies. For example, the target frequency of the branch line 104D having a long wiring length can be set to the 2.4 GHz band, and the target frequency of the branch line 104 having a short wiring length can be set to the 5 GHz band.

FIG. 9B is a schematic diagram of a portion of the flexible printed wiring board of Modification 5. As shown in FIG. As shown in FIG. 9(b), one side of the shield member 205E may not be straight, but may have a recess 2051E, and the branch line 104E may be formed in the recess 2051E.

[Second embodiment]
FIG. 10A is a schematic plan view showing the connection structure between the printed wiring board 402 and the flexible printed wiring board 101F of the imaging unit 400 according to the second embodiment. FIG. 10(b) is a cross-sectional view of the flexible printed wiring board 101F along line XB-XB shown in FIG. 10(a).

A flexible printed wiring board 101F is a flexible printed wiring board including a conductor layer 251 and a conductor layer 252, as in the first embodiment. A flexible printed wiring board 101F has an insulating member 212, a shield member 205 held by the insulating member 212, a signal line 201 and a ground line 202, as in the first embodiment. A plurality of signal lines 201 are arranged on the same conductor layer 252 . The ground line 202 is arranged on the conductor layer 252 on which the signal line 201 is arranged. The ground lines 202 are arranged side by side with the signal lines 201 in the Y direction. The ground line 202 arranged on the conductor layer 252 and the shield member 205 arranged on the conductor layer 251 are electrically connected by vias 206 .

Flexible printed wiring board 101F includes branch line 104F electrically connected to shield member 205 in order to suppress common mode current from propagating through flexible printed wiring board 101F. The tip of the branch line 104F is an open end 211F. The branch line 104F is not formed across a plurality of conductor layers, but is formed in one conductor layer, which is the conductor layer 252 in the second embodiment. That is, the branch line 104</b>F is formed to extend in the X direction and/or the Y direction parallel to the main surface 2051 of the shield member 205 .

In the second embodiment, the branch line 104</b>F is branched from the ground line 202 and electrically connected to the shield member 205 via the ground line 202 and the via 206 . That is, the branch line 104F is a conductor pattern formed to protrude from one side of the ground line 202 extending in the longitudinal direction, that is, a protrusion. The branch line 104F can more effectively return the noise current propagating through the shield member 205 to the connector 102, which is the source of the noise current, and effectively reduce the electromagnetic noise radiated from the flexible printed wiring board 101F. can do.

The flexible printed wiring board 101F of the second embodiment can also be modified in the same manner as the modification of the first embodiment.

[Example]
Experimental results of the flexible printed wiring boards of Examples 1 to 5 and the flexible printed wiring board of Comparative Example 1 will be described. Since the flexible printed wiring boards of Examples 1 to 5 correspond to the flexible printed wiring board 101 of the first embodiment, the same configurations are described using the same reference numerals. The same applies to the flexible printed wiring board of Comparative Example 1.

FIG. 11(a) is a side view showing part of the electronic module 300 in the embodiment, and FIG. 11(b) is a plan view showing part of the electronic module 300 in the embodiment. As shown in FIGS. 11A and 11B, the flexible printed wiring board 101 is stretched straight, and the printed wiring boards 402 and 502 are placed on the same surface of the metal frame 750. It was fixed by the metal member 1007 .

The external dimensions of the printed wiring board 402 were 129.0 mm×210.0 mm×1.6 mm in thickness. The printed wiring board 402 is a six-layer board. Twenty THCV215 ICs manufactured by Thin, which output differential signals, were mounted on the printed wiring board 402 . The frequency of the differential signal was set to 3.53 GHz. Twenty sets of differential signal lines each having two signal lines were provided on the printed wiring board 402 . When a differential signal was output, electromagnetic noise due to common mode current was detected over a wide frequency band from 1 GHz to 6 GHz.

The external dimensions of flexible printed wiring board 101 were 144.0 mm×27.0 mm×thickness of 37.5 μm. Flexible printed wiring board 101 was a single-layer substrate. A shield member 205 made of silver was provided on the entire surface of one side of the flexible printed wiring board 101 by shield printing.

DF40C-70DS-0.4V [51] and DF40C-70DP-0.4V [51] manufactured by Hirose Electric Co., Ltd. were used for connectors 102 and 403 for connecting flexible printed wiring board 101 and printed wiring board 402 .

Ground lines were arranged at both ends and the center of the flexible printed wiring board 101 in the width direction, and 10 pairs of differential signal lines were arranged on both sides of the ground line arranged at the center.

The outer dimensions of the printed wiring board 502 were 50.0 mm×70.0 mm×1.6 mm in thickness. The printed wiring board 502 is a six-layer board.

DF40C-70DS-0.4V [51] and DF40C-70DP-0.4V [51] manufactured by Hirose Electric Co., Ltd. were used for connectors 103 and 503 for connecting flexible printed wiring board 101 and printed wiring board 502 .

Two signal lines included in the differential signal lines provided on the printed wiring board 502 were terminated with a resistance of 100Ω.

The printed wiring boards 402 and 502 were electrically connected to the metal frame 750 with a metal member 1007 having a height of 15.0 mm and a diameter of 6 mm. The metal frame 750 was a metal plate of 325 mm×250 mm×1.0 mm thickness.

In order to measure the electromagnetic noise radiated from the flexible printed wiring board 101, a point at a height of 5 mm from the center of the flexible printed wiring board 101 was set as a measurement start point, and an electric field probe 1008 was placed at the measurement start point. As the electric field probe 1008, EM-6997 manufactured by ELECTRO-METRICS was used. Then, the electric field probe 1008 was moved from the measurement start point toward the printed wiring board 502 at intervals of 2 mm to acquire measurement data at a total of 23 points. The electric field probe 1008 was connected to a spectrum analyzer E4440A manufactured by KEYSIGHT. The spectrum analyzer reads the potential difference between the ground of the electric field probe 1008 and the detection portion, that is, the voltage value as measurement data, and the maximum value among the voltage values at 23 points is taken as the measurement value.

FIG. 12 is a schematic diagram showing the cross-sectional structure of the flexible printed wiring board 101 of the example. The signal line 201 is made of copper. The insulating member 212 is made of polyimide. The wiring width W of each signal line 201 is 55 μm, the distance S between two signal lines 201 of the differential signal lines is 140 μm, the thickness T1 of each signal line 201 is 6 μm, and the thickness T2 of the insulating member 212 is 37.5 μm. and The thickness T3 of the shield member 205 was set to 5 μm, and the distance D between the shield member 205 and the metal frame 750 was set to 15.0 mm. The dielectric constant of polyimide is 3.38.

A common mode current following a loop path including the skin of the shield member 205 and the skin of the metal frame 750 causes electromagnetic noise. Therefore, the shield member 205 is used as the signal line and the metal frame 750 is used as the ground line, and the effective relative permittivity _εr is calculated using a simulator, Hyperlinks manufactured by Macnica Corporation. Here, the interval D is set to 15.0 mm, but the hyperlinks input value is restricted to an upper limit of 10.0 mm. Here, the distance D between the shield member 250 and the metal frame 750 is sufficiently wide compared to the cross-sectional thickness T2+T3 of the wiring, and the effective relative permittivity ε _r It is considered that there is no change in the calculated value. Therefore, the effective relative permittivity _εr was approximated by setting the distance D to an upper limit of 10.0 mm. If the metal frame 750 is not provided, the effective relative permittivity ε _r can be approximated with the upper limit of 10.0 mm based on the same consideration.

The length L of the branch line 104 was calculated using Equation (1). As a result, the effective dielectric constant εr was _1.0008 . Assuming that the noise of 5.300 GHz used in WiFi (registered trademark) wireless communication is reduced, the length L of the branch line 104 is 14.2 mm, and assuming that the noise of 2.412 GHz is reduced , the length L of the branch line 104 is 31.1 mm.

Example 1 is a flexible printed wiring board intended to reduce noise at 5.300 GHz. In Example 1, the width of the branch line 104 was set to 1.5 mm. The branch line 104 was bent perpendicularly to the direction of the printed wiring board 402 at a point 4 mm from the connecting portion with the shield member 205 .

Example 2 is a flexible printed wiring board intended to reduce noise at 2.412 GHz. In Example 2, the width of the branch line 104 was set to 1.5 mm. The branch line 104 was bent perpendicularly to the direction of the printed wiring board 402 at a point 4 mm from the connecting portion with the shield member 205 .

A flexible printed wiring board having no branch line 104 is referred to as Comparative Example 1. FIG. In Examples 1 and 2, the branch line 104 is arranged at a position where the open end 211 thereof overlaps with one side of the printed wiring board 402 .

Table 1 shows the measured noise voltage values of Comparative Example 1, Example 1, and Example 2.

Comparing Comparative Example 1 and Example 1, Example 1 achieved an electromagnetic noise reduction effect of 7 dBμV compared to Comparative Example 1 at 5.3 GHz. Further, when comparing Comparative Example 1 and Example 2, Example 2 achieved an electromagnetic noise reduction effect of 11.1 dBμV compared to Comparative Example 1 at 2.412 GHz.

From the results shown in Table 1, it can be seen that the frequency of electromagnetic noise to be reduced can be set by adjusting the length of branch line 104 . If it is desired to reduce electromagnetic noise of a plurality of different frequencies, a plurality of branch lines with different lengths should be provided.

Next, a comparison was made in the case of changing the direction of the open end 211 of the branch line 104 that reduces the electromagnetic noise of 5.3 GHz. In Example 3, the width of the branch line 104 was set to 1.5 mm. The branch line 104 was bent at a right angle in the direction opposite to the direction of the printed wiring board 402 at a point 4 mm from the connecting portion with the shield member 205 .

Table 2 shows the measured noise voltage values of Comparative Example 1, Example 1, and Example 3.

From the results shown in Table 2, it can be seen that a higher electromagnetic noise reduction effect can be obtained by bending the branch line 104 toward the printed wiring board 402, which is the signal transmission side.

Next, a comparison was made in the case of changing the placement position of the branch line 104 that reduces the noise of 5.3 GHz. In Example 4, the branch line 104 was moved 10 mm from the position of the open end 211 shown in Example 1 toward the printed wiring board 402, that is, in the -X direction. In Example 5, the branch line 104 was moved 10 mm from the position of the open end 211 shown in Example 1 in the direction opposite to the direction of the printed wiring board 402, that is, in the +X direction.

The noise voltage measurements for Examples 4, 1 and 5 are shown in Table 3.

From the results shown in Table 3, it can be seen that by arranging the branch line 104 such that the open end 211 overlaps the printed wiring board 402, a higher electromagnetic noise reduction effect can be obtained.

The present invention is not limited to the embodiments described above, and many modifications are possible within the technical concept of the present invention. Moreover, the effects described in the embodiments are merely enumerations of the most suitable effects resulting from the present invention, and the effects of the present invention are not limited to those described in the embodiments.

In the above-described embodiments, as an example of an electronic device, a camera equipped with a wireless communication unit has been described, but the electronic device is not limited to this. For example, the present invention can be applied to an electronic device having a wireless communication unit near the flexible printed wiring board or an electronic device having no wireless communication unit.

Also, in the above-described embodiments, the flexible printed wiring board mounted on an imaging device such as a digital camera has been described, but the present invention is not limited to this. For example, the present invention can also be applied to rigid printed wiring boards 402 , 502 , 602 . Moreover, the wiring board of the present invention can be applied to electronic devices on which a wiring board is mounted, such as mobile communication devices such as smartphones, tablet PCs, and game machines, and wearable devices.

Further, in the above-described embodiment, the printed wiring board 402 is a rigid printed wiring board, but the printed wiring board 402 may be a flexible printed wiring board. Similarly, although the case where printed wiring board 502 is a rigid printed wiring board has been described, printed wiring board 502 may be a flexible printed wiring board.

The disclosure of the above embodiments includes the following configurations and methods.

(Configuration 1)
a signal line;
a shield member having a main surface along the signal line;
a branch line electrically connected to the shield member and having an open end extending in a direction parallel to the main surface of the shield member;
A wiring board characterized by:

(Configuration 2)
further comprising a ground line arranged in parallel with the signal line in a direction parallel to the main surface of the shield member;
The wiring board according to configuration 1, characterized by:

(Composition 3)
The branch line is branched from the shield member,
The wiring board according to configuration 1 or 2, characterized by:

(Composition 4)
The ground line is electrically connected to the shield member,
The branch line is branched from the ground line,
The wiring board according to configuration 2, characterized by:

(Composition 5)
the signal line includes a first end on a signal transmission side and a second end on a signal reception side;
The branch line is arranged at a position closer to the first end than the second end,
The wiring board according to any one of Structures 1 to 4, characterized in that:

(Composition 6)
The branch line is wired with the tip facing the side where the first end is located,
The wiring board according to configuration 5, characterized by:

(Composition 7)
a portion of the branch line including the tip extends in a direction along the signal line;
The wiring board according to any one of Structures 1 to 6, characterized by:

(Composition 8)
The branch line is L-shaped,
The wiring board according to any one of Structures 1 to 7, characterized by:

を満たす、
ことを特徴とする構成１乃至８のいずれか１項に記載の配線板。 (Composition 9)
Let L be the length of the branch line, f be the frequency, c be the speed of light, and ε _r be the effective dielectric constant,
The frequency is within the range of 700 MHz or more and 66 GHz or less,

satisfy the
The wiring board according to any one of Structures 1 to 8, characterized by:

(Configuration 10)
The frequency is a frequency included in the 2.4 GHz band or the 5 GHz band,
The wiring board according to configuration 9, characterized by:

(Composition 11)
The wiring board is a flexible printed wiring board,
The wiring board according to any one of Structures 1 to 10, characterized by:

(Composition 12)
A flexible printed wiring board according to configuration 11;
A printed wiring board to which the flexible printed wiring board is connected,
An electronic module characterized by:

(Composition 13)
When viewed in a direction perpendicular to the main surface of the printed wiring board, at least a portion of the branch line of the flexible printed wiring board overlaps a ground pattern of the printed wiring board,
13. The electronic module of arrangement 12, characterized in that:

(Composition 14)
at least part of the branch line includes the tip of the branch line;
14. An electronic module according to arrangement 13, characterized in that:

(Composition 15)
at least a portion of the branch line is a portion that is 1/2 or more of the length of the branch line;
14. An electronic module according to arrangement 13, characterized in that:

(Composition 16)
Further comprising an electronic component mounted on the printed wiring board and transmitting a signal to the signal line,
16. The electronic module according to any one of configurations 12 to 15, characterized in that:

(Composition 17)
wherein the electronic component is an image sensor;
17. An electronic module according to arrangement 16, characterized in that:

(Composition 18)
further comprising an electronic unit connected to the flexible printed wiring board and capable of data communication with the electronic component via the flexible printed wiring board;
18. Electronic module according to configuration 16 or 17, characterized in that:

(Composition 19)
Further comprising a wireless communication unit capable of wireless communication with an external device,
19. An electronic module according to any one of arrangements 12-18, characterized in that:

(Configuration 20)
a housing;
an electronic module according to any one of configurations 12-19, disposed inside the housing;
An electronic device characterized by:

DESCRIPTION OF SYMBOLS 101... Flexible printed wiring board 104... Branch line 201... Signal line 211... Open end (tip)

Claims (20)

a signal line;
a shield member having a main surface along the signal line;
a branch line electrically connected to the shield member and having an open end extending in a direction parallel to the main surface of the shield member;
A wiring board characterized by: further comprising a ground line arranged in parallel with the signal line in a direction parallel to the main surface of the shield member;
The wiring board according to claim 1, characterized in that: The branch line is branched from the shield member,
The wiring board according to claim 1, characterized in that: The ground line is electrically connected to the shield member,
The branch line is branched from the ground line,
The wiring board according to claim 2, characterized in that: the signal line includes a first end on a signal transmission side and a second end on a signal reception side;
The branch line is arranged at a position closer to the first end than the second end,
The wiring board according to claim 1, characterized in that: The branch line is wired with the tip facing the side where the first end is located,
The wiring board according to claim 5, characterized in that: a portion of the branch line including the tip extends in a direction along the signal line;
The wiring board according to claim 1, characterized in that: The branch line is L-shaped,
The wiring board according to claim 1, characterized in that: Let L be the length of the branch line, f be the frequency, c be the speed of light, and ε _r be the effective dielectric constant,
The frequency is within the range of 700 MHz or more and 66 GHz or less,

satisfy the
The wiring board according to claim 1, characterized in that: The frequency is a frequency included in the 2.4 GHz band or the 5 GHz band,
The wiring board according to claim 9, characterized in that: The wiring board is a flexible printed wiring board,
The wiring board according to any one of claims 1 to 10, characterized in that: A flexible printed wiring board according to claim 11;
A printed wiring board to which the flexible printed wiring board is connected,
An electronic module characterized by: When viewed in a direction perpendicular to the main surface of the printed wiring board, at least a portion of the branch line of the flexible printed wiring board overlaps a ground pattern of the printed wiring board,
13. Electronic module according to claim 12, characterized in that: at least part of the branch line includes the tip of the branch line;
14. Electronic module according to claim 13, characterized in that: at least a portion of the branch line is a portion that is 1/2 or more of the length of the branch line;
14. Electronic module according to claim 13, characterized in that: Further comprising an electronic component mounted on the printed wiring board and transmitting a signal to the signal line,
13. Electronic module according to claim 12, characterized in that: wherein the electronic component is an image sensor;
17. Electronic module according to claim 16, characterized in that: further comprising an electronic unit connected to the flexible printed wiring board and capable of data communication with the electronic component via the flexible printed wiring board;
17. Electronic module according to claim 16, characterized in that: Further comprising a wireless communication unit capable of wireless communication with an external device,
13. Electronic module according to claim 12, characterized in that: a housing;
and an electronic module according to claim 12, disposed inside the housing.
An electronic device characterized by:

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