JP2007028255A - Dual band antenna and constitution method thereof - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a microminiature dual band antenna capable of transmitting and receiving a 2.4 GHz radio wave and a 5 GHz radio wave by improving a reverse-F antenna (A), generating no dielectric loss, and having a wide tuning frequency band around 5 GHz. <P>SOLUTION: An improved reverse-F antenna is constituted by forming a loading part 2c like (B), a horizontal part 2b is bent like a scalene horizontal U-shape to invent a tentative antenna (C), and a reverse-L shape parasitic element 5 is arranged on the tentative antenna (C) and the electromagnetic field coupling of the parasitic element 5 with the antenna is performed. In this constitution, a portion corresponding to the tentative antenna (C) is tuned to a 2.4 GHz radio wave as the reverse-F antenna and the reverse-L parasitic element 5 tuned to a wide-band radio wave around 5 GHz at λ/4. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a dual band antenna which is improved so as to be suitable for transmitting and receiving 2.4 GHz and 5 GHz radio waves used in a GHz band, particularly, a wireless LAN.

As this type of antenna, an antenna described in Japanese Patent Application Laid-Open No. 2004-064282 is known.
The antenna according to the known invention forms an antenna element that resonates with one radio wave of a dual band at λ / 4 and an antenna element that resonates with the other radio wave at λ / 4, and excites the open end of each antenna element. Capacitance coupling is performed at two specific locations of the device, and at the time when this known invention was filed, the achievement of contributing to the development of the antenna industry as a revolutionary advanced technology was great.

However, subsequent IT technology has progressed steadily, leading to higher demands.
As an antenna specification for wireless LAN, organizing requests from the electronics manufacturer to the antenna technology world,
(A) Further downsizing. For example, the length is 35 mm or less and the height is 6 mm or less.
(B) Dual characteristics of 2.4 GHz and 5 GHz for use in a wireless LAN.
(C) A wide tuning frequency band in the vicinity of 5 GHz.
(D) Prevention of dielectric loss due to the substrate material.
(E) Elimination of restrictions on installation locations (in other words, ultra-thinness).
Further, from the standpoint of an antenna manufacturer, it is desirable that (f) the manufacturing cost is low, and (g) the product performance correction (or performance adjustment) can be easily performed.
JP 2004-64282 A

The present invention has been made in view of the above circumstances,
α) It has a dual characteristic of 2.4 GHz and 5 GHz,
β) has a wide tuning frequency band around 5 GHz,
γ) Ultra small and thin,
δ) It is also possible to prevent dielectric loss (without using a substrate),
ε) Manufacturing cost is low,
ζ) Product performance can be easily modified.
The present invention intends to provide a dual band antenna having a novel configuration.

The progress of research and development that led to the creation of the present invention will be described below with reference to FIG. For convenience of explanation, an X axis parallel to the ground 1 and a Z axis perpendicular to the ground 1 are assumed.
However, this orthogonal coordinate axis XZ is not based on the earth, and does not limit the state of use of the antenna.
FIG. 5A is a schematic diagram of a known inverted-F antenna.
A rising portion 2a extends from the ground 1 in the + Z direction, and a horizontal portion 2b extends from the tip thereof in the + X direction.
The grounding point E of the rising portion 2a has zero impedance, and the tip of the horizontal portion 2b has infinite impedance. A feeding point S is set at a location having an impedance of 50Ω between the two.

When this inverted F-shaped antenna is resonated with a radio wave of frequency f at a quarter wavelength, a standing wave as shown by a broken line f is formed.
Next, when the third harmonic of the radio wave is resonated, a standing wave having a frequency of 3f is formed as indicated by a one-dot chain line 3f.
This is a dual-band antenna having a frequency ratio of 1: 3, and the one-to-two dual-band characteristic which is the object of the present invention cannot be obtained. (Note) The frequency ratio between 2.4 GHz and 5 GHz used for wireless LAN is about 1: 2.

A method of modifying the above inverted F-shaped antenna so as to resonate at the frequency f and the frequency 2f will be described.
A portion where the standing wave (current value) of 3f indicated by a one-dot chain line in FIG. 5A is zero is a portion where the voltage value is maximum. When loading is applied to this part, the harmonic frequency is reduced. That is, 3f approaches 2f.
In this way, it is possible to resonate (tune) the frequencies f and 2f as in the improved inverted F antenna shown in FIG.
With the above improvement, the fundamental wave f slightly changes, but can be modified in design.
Giving the above-mentioned loading means increasing the diameter locally for a linear antenna, increasing the width locally for a strip antenna, or increasing the capacitance locally to the ground 1. To have it.

The above-mentioned improved inverted F-shaped antenna provides the dual characteristics of 2.4 GHz and 5 GHz in the item (b) within the purpose of the seven items from the item (a) to the item (g). The tuning frequency band in the vicinity is narrow, and further miniaturization has not been achieved, and there is no particular effect on prevention of dielectric loss.
Therefore, the present inventors have continued intensive studies to further improve the improved antenna.
FIG. 5 (C) shows a “proposed modified inverted F-shaped antenna” in the course of research to complete the present invention.

Comparing (C) in FIG. 5 to (B), the rising portion (2a, 4a) extends from the ground 1 in the + Z direction, and the feeding point S is set at a location where the impedance is 50Ω. is there.
The linear antenna element extending in the + X direction from the feeding point S in (B) is bent into an unequal side U-shape in (C).
The above bending is performed at both ends of the loading portion. As a result, the loading portion 2c that is horizontal in FIG. 5B becomes the vertical loading portion 4c in FIG.
If the end in the + X direction of the unequal side U-shape is folded down in the −Z direction as indicated by the dotted line 4e and the tip thereof is opposed to the ground 1 to provide a capacitance, the length in the X-axis direction is increased. It is further shortened.

As a result, the improved inverted-F antenna (B) was able to significantly shorten the mechanical length dimension in the X-axis direction with almost no change in its electrical operation.
However, since the electrical operation has hardly changed, the tuning frequency band in the vicinity of 5 GHz is narrow.

Therefore, the inventors added an inverted L-type parasitic element 5 as shown in FIG.
The inverted L-type parasitic element 5 is an antenna element that resonates at λ / 4 with respect to a radio wave having a frequency of 2f (specifically, 5 GHz), and grounds one end thereof to the ground 1.
The open end opposite to the grounding portion is electromagnetically coupled C to the vertical loading portion 4c.
Recall that the vertical loading section was the place where the voltage value of the standing wave was the maximum.
According to the configuration of FIG. (D), the inverted L-type parasitic element 5 is tuned in a wide frequency band with respect to a radio wave having a frequency of 2f (specifically, 5 GHz).
The inverted L-type parasitic element 5 is not necessarily limited to an inverted L-shape. In short, any antenna element that resonates at λ / 4 with respect to a radio wave having a higher frequency within the dual tuning performance may be used. Accordingly, an application example in which this is constituted by a meander type parasitic element is conceivable.

As a specific configuration based on the principle described above, the dual antenna according to the invention of claim 1 is a dual-band antenna that transmits and receives a radio wave having a frequency f in the GHz band and a radio wave having a frequency of about 2f (see FIG. 1). ),
Assuming Cartesian coordinates X-Z and setting the +-direction for each coordinate axis,
A rising portion 4a extending from the ground 1 in the + Z direction;
A short horizontal portion 4b connected to the tip of the rising portion 4a and extending in the + X direction;
A vertical loading portion 4c connected to the short horizontal portion 4b and extending in the + Z direction;
A long horizontal portion 4d connected to the vertical loading portion 4c and extending in the -X direction;
It has
In addition, the other end (open end) of the parasitic element 5 whose one end is grounded to the ground 1 and resonates at a frequency of about 2 f is electromagnetically coupled to the vertical loading portion 4 c so as to be opposed to and separated from the vertical loading portion 4 c. To do.
However, the coordinate axes X and Z, + and − of the coordinate axes, and the terms “horizontal” and “vertical” are for convenience used for easy understanding of the explanation, and are based on the earth. The posture is not limited.

The dual antenna according to the invention of claim 2 is in addition to the constituent features of the invention of claim 1 (see FIG. 3).
The ground 1, the rising portion 4a, the short horizontal portion 4b, the vertical loading portion 4c, the long horizontal portion 4d, and the parasitic element 5 are a sheet metal member formed integrally by punching from a metal plate,
By supporting the ground 1, the rising portion 4a, the short horizontal portion 4b, the vertical loading portion 4c, the long horizontal portion 4d, and the parasitic element 5 connected to the ground 1 are independent without interposing a solid dielectric. It is characterized by obtaining.

The dual antenna according to the invention of claim 3 is in addition to the constituent features of claim 2 (see FIG. 3),
A coaxial cable 6 is connected to the integrally formed connecting member made of sheet metal to constitute one assembly component.

The dual antenna according to the invention of claim 4 is in addition to the constituent features of claim 1 or claim 3 (see FIGS. 1 to 3),
The parasitic element (5) resonating at a frequency of about 2f is an L-shaped member composed of a side in the X-axis direction and a side in the Z-axis direction.

In addition to the constituent features of the first to fourth aspects, the dual antenna according to the invention of claim 5 (see FIGS. 1 to 3),
An end in the −X direction of the long horizontal portion 4d is bent in the −Z direction to form a folded portion 4e, and the −Z direction end faces the ground 1.

The dual antenna according to the invention of claim 6 is added to the constituent features of the inventions of claims 1 to 5,
The electromagnetic field coupling portion between the parasitic element 5 and the vertical loading portion 4) is critically coupled, or is slightly more tightly coupled than the critical coupling state.

The configuration of the inventive method according to claim 7 (see FIG. 5),
In the method of constructing a dual-band antenna that improves the inverted F-shaped antenna and transmits and receives GHz band radio waves,
I. Assuming that the lower frequency of the dual band is f and the higher frequency is about 2f,
B. Assuming Cartesian coordinates X-Z, set +-in the direction of the coordinate axes,
C. An F-shaped antenna provided with a rising portion 2a extending from the ground 1 in the + Z direction, a horizontal portion 2b extending in the + X direction from the tip of the rising portion, and a feeding point S set in the middle of the horizontal portion 2b age,
D. By bending the horizontal portion 2b into an unequal side U-shape, a short horizontal portion 4b connected to the tip of the rising portion 4a and extending in the −X direction, and a vertical portion 4c connected to the tip of the short horizontal portion 4b, And a long horizontal portion 4d extending in the + X direction from the tip of the vertical portion 4c,
E. Loading the vertical portion 4c to form a vertical loading portion 4c;
F. In addition, the open end of “the parasitic element 5 that resonates with a radio wave having a frequency of about 2 f” with one end grounded to the ground 1 is “the connection portion between the long horizontal portion 4 d and the inverted L-shaped parasitic element 5”. By facing the vicinity and electromagnetic field coupling,
α. When transmitting and receiving radio waves of the lower frequency f, the inverted F-shaped antenna portion bent into an unequal side U-shape is allowed to act as a λ / 4 inverted F-shaped antenna,
β. When transmitting and receiving a radio wave having a higher frequency of about 2f, the parasitic element (5) is made to act as a λ / 4 antenna.

When the dual-band antenna according to the first aspect of the invention is applied, the lower frequency f (for example, 2.4 G) of the dual performance is tuned as an inverted F antenna, and the higher frequency is about 2 f (for example, 5 GHz). ) Can be tuned in a wide frequency band as a λ / 4 antenna, and is suitable as an antenna for a wireless LAN.
Moreover, the antenna can be remarkably reduced in size as compared with an antenna according to the prior art (for example, an inverted F antenna).

When the invention of claim 2 is used in combination with the invention of claim 1, dielectric loss due to the substrate can be completely prevented at a low manufacturing cost.
That is, the dual-band antenna according to the invention of claim 1 can be manufactured as a conductive pattern on a substrate, or can be manufactured by sheet metal processing, and in any case, excellent effects of small size and wide band can be obtained. However, when manufacturing as a conductive pattern of a substrate, an expensive material substrate (for example, a Teflon (registered trademark) substrate) must be used to reduce dielectric loss.
In this regard, when the invention of claim 2 is used in combination, there is no possibility of causing a dielectric loss because the substrate is not used.

When the invention of claim 3 is used in combination with the invention of claim 2, a single antenna device that can be a product having market distribution is formed by utilizing the characteristic of the sheet metal integrated structure that is the structure of claim 2.
As a result, the wireless device manufacturer can receive a high-quality antenna assembly manufactured in a specialized factory and quickly and easily incorporate it.
In this way, the division of labor in the antenna industry is established, which greatly contributes to the overall development of the IT industry.

According to the invention of claim 4, the “parasitic element that resonates at a frequency of about 2 f”, which is an essential component of claim 1, can be configured at a low cost, a small size, and a light weight, particularly for mass production by sheet metal processing. Is suitable.
That is, the parasitic element in claim 1 is required to resonate at λ / 4 with respect to a radio wave having a frequency of about 2f, and can be configured as a straight wire antenna element, and is configured in a solenoid shape. It can also be configured in a meander shape. However, when this claim 4 is applied to form an inverted L-shape, it is smaller than the filament antenna element, thinner than the solenoid element, and more self-supporting (stiffness when configured as a sheet metal) than the meander element. Big and practical value.

  According to the invention of claim 5, the mechanical length of the dual band antenna according to claim 1 can be further shortened, and the production cost is hardly increased.

  When the invention of claim 6 is applied, the tuning frequency band for the radio wave having the higher frequency in the dual band performance can be widened to the maximum, or the maximum antenna gain can be obtained in the desired frequency band. You can also.

According to the invention method of claim 7, the known inverted-F antenna is improved to constitute a dual band antenna, and a wide tuning frequency band can be obtained in the vicinity of the higher frequency of the dual band,
In addition, the antenna device can be significantly smaller and lighter than the conventional antenna device.

FIG. 2 is a trihedral view showing one embodiment of a dual-band antenna according to the present invention,
(A) is a plan view, (B) is a front view, and (C) is a side view.
Please note that different coordinate axes are added to each of the diagrams (A), (B), and (C).
This antenna device can be used in any desired posture, and there is essentially no distinction between up and down and left and right. However, for convenience of explanation, orthogonal three axes X, Y, and Z are assumed as appended to the drawings.
For convenience of explanation, + -direction is designated for the X axis and the Z axis. There is no need to specify the direction of the Y axis.
The coordinate axes are common to FIGS. 2 and 3 described later. However, it is impossible to escape from the technical scope of the present invention even if the X-axis and Z-axis are reversed in the positive and negative directions. (Note) When these FIGS. 1 to 3 are compared with FIG. 5 described above, the coordinate axes are the same, but the shape of the antenna element is opposite (mirror symmetry).

(See FIG. 1) The dual-band antenna of this embodiment can be seen in (C side view)
The overall shape is similar to L-shaped steel (but much smaller).
Reference numeral 1 indicates a ground, and an attachment hole 1a is formed so as to be easily connected to a ground plate of a wireless device.
As shown in (B front view), several types of antenna elements are integrally connected from the ground 1 in the + Z direction.

FIG. 1 is a schematic diagram in which the front view of FIG. 2B is extracted and the dimension in the Z-axis direction is enlarged for easy viewing. Accordingly, FIG. 1 is not an accurate projection of this embodiment. Parallel diagonal lines symbolize the ground. Spots are intended to facilitate reading.
A rising portion 4a extends from the ground 1 in the + Z direction.
A short horizontal portion 4b extends in the + Z direction from the tip (upper end in the figure) of the rising portion 4a.
A wide vertical loading portion 4c is continuously provided in the + Z direction from the front end (right end in the figure) of the short horizontal portion.
A long horizontal portion 4d extends in the −X direction from the tip (upper end in the figure) of the vertical loading portion, and the tip is bent downward to form a folded portion 4e.

On the other hand, the inverted L-type parasitic element 5 extends from the ground 1 in the + Z direction, bends in the -X direction in the middle, and has its tip (left end in the figure) facing the vertical loading portion 4c to be electromagnetically coupled. c is formed.
FIG. 4 shows the VSWR (voltage standing wave ratio) of the dual-band antenna according to this embodiment.
A clear dual-band characteristic appears at 2.4 GHz and 5 GHz, and a broadband property is recognized in the vicinity of 5 GHz.

It is an experimental fact that the antenna device of FIG. 1 has shown the antenna performance of FIG.
Thus, the reason why a wide tuning frequency band is obtained in the vicinity of 5 GHz is as follows according to the stagger theory.
In other words, it is considered that the two resonance states of the modified inverted-F antenna and the λ / 4 antenna element (inverted L-type parasitic element 5) are combined (capacitive coupling), and a broadband tuning characteristic has appeared. It is done.

As can be inferred from the above theory, the tuning characteristics change depending on the density of electromagnetic coupling between the inverted L-type parasitic element 5 and the vertical loading portion 4c.
In general, when two tuning circuits are capacitively coupled or inductively coupled, if the coupling is sparse, a unimodal tuning characteristic is exhibited, and if the coupling is dense, a bimodal tuning characteristic is exhibited. And in the middle state between the two, the top of the peak becomes flat, so to speak, it shows a high-quality tuning characteristic. This state is called critical coupling.
In the dual-band antenna of the present invention, it is desirable that the inverted L-type parasitic element 5 and the vertical loading unit 4c are made to be in a critical state or slightly more tightly coupled than the critical state.
When the coupling is increased beyond the critical state, the flat portion at the top of the tuning curve hangs down and approaches the bimodal tuning curve, and the tuning frequency band becomes wider.
In the sixth aspect of the present invention, “tightly coupled than the critical state” does not mean that the region is densely bounded indefinitely, but “tightly couples within a range in which the hanging portion of the tuning curve can withstand transmission / reception”.
That means.

Adjustment of the coupling state can be easily performed because it is only necessary to change either (or both) the distance and the facing area of the portion where the inverted L-type parasitic element 5 and the vertical loading portion 4c face each other. . The correction of the facing area actually changes the length of the two opposing sides.
It has been extremely difficult to finely adjust the characteristics of mass-produced antenna devices with high accuracy using the conventional inverted-F antenna, but can be performed quickly and easily in the present invention.

FIG. 3 is a perspective view schematically showing the dual band antenna of the embodiment shown in FIG. It is not a realistic projection because it is schematic.
The items that have been modified for the convenience of reading are as follows.
I. The plate thickness is increased compared to the actual model. Enlarge the dimension in the Z direction than the actual shape, and
C. A bent portion between the ground 1 and the rising portion 4a and a bent portion between the ground 1 and the inverted L-type parasitic element 5 are rounded.

Since this example is created by sheet metal processing, when the ground 1 is attached to a wireless device, other antenna elements can stand by themselves.
Furthermore, since it is a sheet metal member, it is easy to adjust the density of the connection described above. Moreover, because it is made of sheet metal, it is suitable for industrial production and can produce a large amount of products of uniform quality.
In addition, since the ground 1 is made of sheet metal, it can be easily and firmly attached to the device to which it is attached.

The core wire of the coaxial cable 6 is connected and connected (soldered) to the feeding point S of the short horizontal portion 4b, and the external conductor is grounded E (soldered) to the ground 1.
Although not shown, a coaxial socket is connected to multiple ends of the coaxial cable 6 and can be quickly and easily connected to an output end of a high-frequency circuit (not shown).
If it is configured as one assembly component as shown in FIG. 3, it will generate market distribution, support the division of labor of the antenna industry, and contribute to the development of the IT industry comprehensively.

  In this embodiment (FIG. 3), which is a dual band antenna of 2.4 GHz and 5 GHz, the mechanical length dimension L of the portion excluding the ground 1 is 43.8 millimeters, and the height dimension H is 5 millimeters. The miniaturization that could not be achieved with the prior art was brilliantly realized.

The figure which attached electromagnetic field coupling c and the coordinate axis to the typical front view of the dual band antenna concerning one embodiment of the present invention. It is a 3rd page figure of the dual band antenna concerning one embodiment of the present invention, (A) is a top view, (B) is a front view, (C) is a side view. Schematic perspective view of the dual band antenna according to the embodiment shown in FIG. VSWR diagram shown for explaining the operational effect of the dual band antenna according to the embodiment shown in FIG. It is shown in order to explain the research process which created the present invention, (A) is a schematic diagram of a known inverted F-shaped antenna, (B) is an inverted F-shaped antenna improved to reduce the frequency of harmonics Schematic diagram, (C) is a schematic diagram of a prototype antenna improved so as to shorten the mechanical length dimension of the improved inverted-F antenna, and (D) shows the principle of the present invention. Schematic diagram of dual-band antenna with further improved characteristics

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Ground 1a ... Mounting hole 2a ... Rising part 2b ... Horizontal part 2c ... Loading part 3 ... High frequency circuit 4a ... Rising part 4b ... Short horizontal part
4c ... Vertical loading section
4d ... Long horizontal part
4e ... Folding part
5 ... Inverted L-shaped parasitic element
6 ... Coaxial cable
C: Electromagnetic coupling
E ... Grounding
H: Mechanical length dimension excluding ground L: Mechanical height dimension excluding ground S: Feeding point
X: Coordinate axis in the length direction of the antenna element
Y: Coordinate axis in the thickness direction of the antenna element
Z: Coordinate axis in the height direction of the antenna element

Claims (7)

In a dual-band antenna that transmits and receives radio waves with a frequency f in the GHz band and radio waves with a frequency of about 2f,
Assuming Cartesian coordinates X-Z and setting the +-direction for each coordinate axis,
A rising portion (4a) extending in the + Z direction from the ground (1);
A short horizontal portion (4b) connected to the tip of the rising portion (4a) and extending in the + X direction;
A vertical loading portion (4c) connected to the short horizontal portion (4b) and extending in the + Z direction;
A long horizontal portion (4d) connected to the vertical loading portion (4c) and extending in the -X direction;
It has
In addition, the open end of the parasitic element (5) having one end grounded to the ground (1) and resonating at a frequency of about 2f is electromagnetically coupled to face the vertical loading portion (4c). And a dual-band antenna. The ground (1), the rising portion (4a), the short horizontal portion (4b), the vertical loading portion (4c), the long horizontal portion (4d), and the parasitic element (5) are formed by punching from a metal plate. And
By supporting the ground (1), a rising part (4a), a short horizontal part (4b), a vertical loading part (4c), a long horizontal part (4d), and a parasitic element (5) connected thereto are provided. The dual-band antenna according to claim 1, wherein the dual-band antenna can stand on its own without interposing a solid dielectric.   The dual-band antenna according to claim 2, wherein a coaxial cable (6) is connected to the integrally formed sheet metal coupling member to constitute one assembly component.   The parasitic element (5) resonating at a frequency of about 2f is an L-shaped member composed of a side in the X-axis direction and a side in the Z-axis direction. Dual band antenna described in any one.   An end in the −X direction of the long horizontal portion (4d) is bent in the −Z direction to form a folded portion (4e), and the −Z direction end faces the ground (1). The dual-band antenna according to any one of claims 1 to 4.   The electromagnetic coupling portion between the parasitic element (5) and the vertical loading portion (4c) is critically coupled or more tightly coupled than a critical coupling state. The dual-band antenna according to claim 5. In the method of constructing a dual-band antenna that improves the inverted F-shaped antenna and transmits and receives GHz band radio waves,
I. Assuming that the lower frequency of the dual band is f and the higher frequency is about 2f,
B. Assuming Cartesian coordinates X-Z, set +-in the direction of the coordinate axes,
C. A rising portion (2a) extending in the + Z direction from the ground (1), a horizontal portion (2b) extending in the + X direction from the tip of the rising portion, and a feeding point set in the middle of the horizontal portion (2b) ( The F-type antenna provided with S) is used as a base,
D. The horizontal part (2b) is bent into an unequal side U-shape, connected to the tip of the rising part (4a) and extended in the -X direction, and at the tip of the short horizontal part (4b) The connected vertical part (4c) and a long horizontal part (4d) extending in the + X direction from the tip of the vertical part (4c) are configured,
E. Electrical loading is applied to the vertical part (4c) to form a vertical loading part (4c),
F. In addition, the open end of the “parasitic element (5) that resonates with a radio wave having a frequency of about 2 f” with one end grounded to the ground (1) is connected to the long horizontal portion (4d) and the inverted L-shaped parasitic element. (5) By connecting it with the electromagnetic field opposite to the vicinity of the "connection part with"
α. When transmitting / receiving radio waves of the lower frequency f in the dual, the inverted F-shaped antenna portion bent into an unequal side U-shape is tuned as a λ / 4 inverted F-shaped antenna,
β. A method of constructing a dual-band antenna, wherein when the radio wave having a higher frequency of about 2f is transmitted / received, the parasitic element (5) is tuned as a λ / 4 antenna.

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