This application claims the benefit of priority of Japanese Patent Application Number 2014-181664, filed Sep. 5, 2014, the entire content of which is hereby incorporated by reference.
1. Field of the Invention
The present disclosure relates to a luminaire capable of wireless communication.
2. Description of the Related Art
Luminaires capable of wireless communication have been conventionally known. A luminaire capable of wireless communication includes an antenna for wireless communication, and performs processes according to wireless signals received by the antenna (for example, see Japanese Unexamined Patent Application Publication No. 2013-145634).
It is aesthetically desirable that the antenna included in the luminaire is unnoticeable in the state where the luminaire is installed. The antenna is therefore placed in the luminaire body of the luminaire or in a housing in which a power circuit is contained.
However, the luminaire body and the housing containing the power circuit are typically made of metal, for safety measures and the like. Such a metal housing blocks electric waves, which causes a problem in ensuring the communication function of the antenna.
The present disclosure accordingly has an object of providing a luminaire that ensures the communication function of wireless communication and also improves the communication quality.
To achieve the object stated above, a luminaire according to one aspect of the present disclosure includes: a power circuit that supplies power to a light source; an antenna that at least one of transmits and receives a wireless signal; and a metal housing that contains the antenna and the power circuit. The metal housing has an opening, and the antenna and the opening are arranged to cause a polarization plane of an electric wave most strongly radiated from the antenna and a polarization plane of an electric wave most strongly radiated from the opening to substantially coincide with each other.
This structure ensures the communication function of wireless communication and also improves the communication quality.
The figures depict one or more implementations in accordance with the present teaching, by way of examples only, not by way of limitations. In the figures, like reference numerals refer to the same or similar elements.
The following describes a luminaire according to each of the embodiments of the present disclosure in detail, with reference to drawings. Each of the embodiments described below shows a general or specific example. The numerical values, shapes, materials, structural elements, the arrangement and connection of the structural elements, etc. shown in the following embodiments are mere examples, and therefore do not limit the scope of the present disclosure. Of the structural elements in the following embodiments, structural elements not recited in any one of the independent claims representing superordinate concepts are described as optional structural elements.
Each of the drawings is a schematic diagram, and does not necessarily provide exact illustration. The same structural members are given the same reference signs in the drawings.
An overview of a luminaire according to Embodiment 1 is described first, with reference to
Luminaire 1 according to this embodiment is capable of wireless communication. In detail, luminaire 1 performs wireless communication with another apparatus such as a remote control or a mobile information terminal such as a smartphone or a tablet terminal. In more detail, luminaire 1 transmits a wireless signal to another apparatus, or receives a wireless signal from another apparatus. For example, in the case where luminaire 1 receives a wireless signal from another apparatus, luminaire 1 performs a process such as turning on the light, turning off the light, dimming, or toning based on the received wireless signal.
Luminaire 1 includes light source 2, luminaire body 10, feeding socket 20, non-feeding socket 30, reflector 40, circuit case 50, power circuit 60, and wireless module 70 including antenna 71, as illustrated in
Luminaire 1 has one surface (i.e. the surface opposite to reflector 40) of luminaire body 10 fixed to an installation surface such as a ceiling. Luminaire 1 is long, as illustrated in
Each structural member in luminaire 1 is described in detail below.
Light source 2 is a light source for illumination including a light emitting module having a light emitting element, and emits predetermined light. Light source 2 is removably placed in luminaire body 10.
In this embodiment, light source 2 is a straight-tube light emitting diode (LED) lamp. The straight-tube LED lamp includes, for example, a long housing such as a glass bulb, an LED module placed in the housing, and a feeding base and non-feeding base provided at the ends of the housing.
The LED module is actually a chip-on-board (COB) light emitting module in which an LED chip is mounted directly on a board, though the LED module is not limited to this. For example, the LED module may be a light emitting module in which a surface-mount-device (SMD) LED element is used as a light emitting element. The SMD LED element is a packaged LED element obtained by mounting an LED chip in a cavity of a case made of resin and enclosing phosphor-containing resin in the cavity. The light emitting element included in light source 2 may be any other solid light emitting element, for example, a semiconductor light emitting element such as a semiconductor laser or an electroluminescence (EL) element such as an organic EL or inorganic EL element.
Luminaire body 10 is an example of a metal structure. Luminaire body 10 is formed by bending a plate member made of metal such as aluminum to have an opening on the lower side.
Luminaire body 10 is a container that contains circuit case 50 (power circuit 60) and wireless module 70 (antenna 71). In detail, luminaire body 10 is substantially a long rectangular parallelepiped, and has its open surface covered by reflector 40. Feeding socket 20 and non-feeding socket 30 are provided at the respective ends of luminaire body 10 so as to protrude downward below reflector 40.
In this embodiment, luminaire body 10 and reflector 40 constitute a metal housing that contains power circuit 60 and antenna 71.
Luminaire body 10 has opening 11. In this embodiment, only one opening 11 is formed in a side surface of luminaire body 10, as illustrated in
Opening 11 is a slit opening. In detail, opening 11 is substantially rectangular in shape. Opening 11 is formed, for example, with its long side direction (Y axis direction) being parallel to the long side direction of luminaire body 10. The length (L in
The term “substantially half the wavelength” means that the length is essentially or approximately equal to the half wavelength. The term “substantially half the wavelength” may include the range of plus and minus several % (e.g. 5%) with respect to the half wavelength. For example, the length of the long side of opening 11 may be several % shorter than half (λ/2) the wavelength λ corresponding to the wireless signal frequency. The same applies to other similar descriptions.
Feeding socket 20 is a socket for feeding power to light source 2. Feeding socket 20 is formed, for example, by insert molding using a resin material and a pin receiving terminal made of metal.
A base pin (e.g. a pair of L-shaped pins) of a feeding base of light source 2 is inserted in feeding socket 20. The inserted base pin is in contact with the metal pin receiving terminal in feeding socket 20. For example, the pin receiving terminal is connected to power circuit 60 in circuit case 50. Power for lighting light source 2 can thus be fed to light source 2 via feeding socket 20.
Non-feeding socket 30 is a non-feeding socket for holding light source 2. Non-feeding socket 30 is formed, for example, by injection molding using a resin material. A base pin (e.g. a T-shaped pin) of a non-feeding base of light source 2 is inserted in non-feeding socket 30.
Reflector 40 is an example of a metal structure. Reflector 40 is formed by processing a plate member made of metal, like luminaire body 10. For example, reflector 40 is painted white or milk white so that its lower surface has a reflection function. Although this embodiment describes an example where reflector 40 is separate from luminaire body 10, reflector 40 may be formed integrally with luminaire body 10.
Circuit case 50 is a case that contains power circuit 60. Circuit case 50 is formed, for example, by bending a plate member made of metal such as aluminum.
For example, circuit case 50 has a through hole through which a lead wire (not illustrated) is inserted. The lead wire electrically connects power circuit 60 and antenna 71.
Circuit case 50 may contain not only power circuit 60 but also antenna 71, as in Embodiment 3 described later. Detailed description will be given in Embodiment 3.
Power circuit 60 is a circuit (lighting circuit) for supplying power to light source 2. In detail, power circuit 60 converts AC power supplied from system power or the like via a cable (not illustrated) into DC power and supplies the power to light source 2.
Power circuit 60 is formed, for example, on a printed wiring board. In detail, power circuit 60 includes a diode bridge rectifier circuit for converting AC power into DC power and a DC-DC converter. Power circuit 60 may be realized as one integrated circuit (IC) having the same functions as a rectifier circuit and a DC-DC converter.
Wireless module 70 includes antenna 71, wireless control circuit 72, printed wiring board 73, and connector 74, as illustrated in
Antenna 71 is a pattern antenna for transmitting or receiving a wireless signal. In other words, antenna 71 is a conductive pattern formed on printed wiring board 73, as illustrated in
Note that antenna 71 is any antenna that performs at least one of transmission and reception of a wireless signal, and is not limited to a pattern antenna. For example, antenna 71 may be a chip antenna.
In this embodiment, antenna 71 is a substantially L-shaped pattern antenna. As illustrated in
Although antenna 71 is not limited to be substantially L-shaped but may be linear or the like in shape, substantially L-shaped antenna 71 enables a reduction in size of wireless module 70.
In this embodiment, the frequency band of the wireless signal transmitted or received by antenna 71 is the ultra high frequency (UHF) band or the super high frequency (SHF) band.
Wireless control circuit 72 is an integrated circuit that controls the transmission or reception of the wireless signal by antenna 71. In this embodiment, wireless control circuit 72 obtains a predetermined command included in the wireless signal which antenna 71 has received from a remote control or the like. Wireless control circuit 72 controls power circuit 60 according to the obtained command. In detail, wireless control circuit 72 controls power circuit 60 to turn on or off light source 2.
In this embodiment, wireless control circuit 72 performs communication using ZigBee® which is one of the standards for wireless personal area networks (WPANs). The communication method of wireless control circuit 72 is, however, not limited to this, and may be Bluetooth® or a wireless local area network (LAN).
Printed wiring board 73 is a board on which antenna 71 and wireless control circuit 72 are mounted.
Connector 74 is a connector for connecting power circuit 60 and each of wireless control circuit 72 and antenna 71. For example, a receiving-side connector (not illustrated) to which connector 74 is connectable is provided in luminaire body 10. The receiving-side connector is electrically connected to power circuit 60 via a lead wire or the like. By connecting connector 74 to the receiving-side connector, wireless control circuit 72 can be electrically connected to power circuit 60.
Connecting connector 74 and the receiving-side connector allows the position of wireless module 70 in luminaire body 10 to be fixed. The positional relationship between antenna 71 and opening 11 can thus be determined, as described later.
Power circuit 60 and wireless control circuit 72 may be connected directly to each other via a lead wire.
Although power circuit 60 and the structure including antenna 71 and wireless control circuit 72 are provided on different boards in this embodiment, these components may be provided on one board. In this case, a shorter wire length contributes to more stable operation, and a smaller number of components contributes to lower cost.
The following describes the positional relationship between antenna 71 and opening 11 formed in luminaire body 10 according to this embodiment, with reference to
In this embodiment, luminaire body 10 is combined with reflector 40 to constitute a metal housing which is substantially a rectangular parallelepiped. The metal housing has opening 11 and contains antenna 71 inside, as illustrated in
In this case, since antenna 71 in the metal housing and opening 11 are close to each other, antenna 71 and opening 11 are coupled to each other. As a result, an electric wave generated from antenna 71 causes a current to flow on the surface of the metal housing. In other words, opening 11 of the metal housing functions as a slot antenna. In the slot antenna, an electric field is generated in the short side direction of opening 11. Hence, in the example illustrated in
In this embodiment, antenna 71 and opening 11 are arranged so that the polarization plane of the electric wave most strongly radiated from antenna 71 and the polarization plane of the electric wave most strongly radiated from opening 11 substantially coincide with each other. In detail, antenna 71 is positioned so that the polarization plane of the electric wave most strongly radiated from antenna 71 is at an angle of at least ±15° with respect to the long side direction of opening 11.
The strength of the electric wave radiated from antenna 71 is described below, with reference to
As can be understood from the comparison of
Accordingly, antenna 71 is positioned so that root portion 71b is perpendicular to the long side direction of opening 11, as illustrated in
The positional relationship between opening 11 of the metal housing and antenna 71 and the maximum gain of the electric wave radiated from opening 11 are described below, with reference to
The horizontal axis in
As illustrated in
The maximum strength of the main lobe is about 3 dB in the case where the angle is 90°, and about −23 dB in the case where the angle is 0°, as illustrated in
The above indicates that antenna 71 is to be positioned so that the polarization plane of the electric wave most strongly radiated from antenna 71 is at an angle of at least ±15° with respect to the long side direction of opening 11. In other words, antenna 71 is to be positioned so that the polarization plane of the electric wave most strongly radiated from antenna 71 is in the range greater than or equal to 15° and less than or equal to 165°, and greater than or equal to 195° and less than or equal to 345°, with respect to the long side direction of opening 11.
As described above, luminaire 1 according to this embodiment includes: power circuit 60 that supplies power to light source 2; antenna 71 that at least one of transmits and receives a wireless signal; and luminaire body 10 that contains antenna 71 and power circuit 60. Luminaire body 10 has opening 11, and antenna 71 and opening 11 are arranged to cause a polarization plane of an electric wave most strongly radiated from antenna 71 and a polarization plane of an electric wave most strongly radiated from opening 11 to substantially coincide with each other.
Thus, in this embodiment, the metal housing has opening 11 that functions as a slot antenna to radiate the electric wave from antenna 71 placed in the metal housing to the outside. This ensures the communication function of wireless communication.
Moreover, in this embodiment, antenna 71 and opening 11 are arranged so that the polarization plane of the electric wave most strongly radiated from antenna 71 and the polarization plane of the electric wave most strongly radiated from opening 11 substantially coincide with each other. The strength of the electric wave from opening 11 can be increased in such a way, as illustrated in
For example, the metal housing is substantially a rectangular parallelepiped, opening 11 is substantially rectangular in shape, a long side direction of opening 11 is parallel to a long side direction of the metal housing, and antenna 71 is positioned with the polarization plane of the electric wave most strongly radiated from antenna 71 being at an angle of at least ±15° with respect to the long side direction of opening 11.
The strength of the electric wave from opening 11 can be increased in such a way, thus improving the communication quality of wireless communication.
For example, opening 11 is substantially rectangular in shape, and a length of a long side of opening 11 is greater than or equal to substantially half a wavelength corresponding to a frequency of the wireless signal.
This enables efficient transmission or reception of the wireless signal.
For example, antenna 71 is mounted on printed wiring board 73.
This enables a reduction in size of the antenna and a reduction in the number of components.
For example, opening 11 is a slit opening.
Such opening 11 can efficiently function as a slot antenna.
The following describes a luminaire according to Embodiment 2. The following description mainly focuses on the differences from Embodiment 1, and may omit the same parts.
In this embodiment, first opening 120 is formed in side surface 110 of the metal housing instead of opening 11 in Embodiment 1, as can be seen from the comparison with
First opening 120 is described in detail below.
In this embodiment, first opening 120 is formed in side surface 110 of the metal housing, as illustrated in
First opening 120 is a slit opening. As illustrated in
Width d of first opening 120 is substantially constant. Let L1 be the length of long side portion 120a, and L2 be the length of each short side portion 120b. The length of first opening 120 along the slit direction is L1+2×L2. Thus, the length of first opening 120 along the slit direction is the total length of long side portion 120a and two short side portions 120b.
In this embodiment, the length of first opening 120 along the slit direction is greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency. For example, when the wireless signal uses the frequency band of 2.4 GHz, half the wavelength corresponding to this frequency is about 62 mm. Hence, for example, first opening 120 illustrated in
With first opening 120 illustrated in
Although
The following describes examples of such an opening group with reference to
As illustrated in
First plate portion 111 is a part surrounded by the plurality of openings (i.e. closing plate). Second plate portion 112 is a part outside the plurality of openings. Connecting portion 113 is a part between an end of one of the plurality of openings and an end of another one of the plurality of openings, and connects first plate portion 111 and second plate portion 112. In other words, the plurality of openings and the plurality of connecting portions 113 are provided between first plate portion 111 and second plate portion 112.
First plate portion 111, second plate portion 112, and connecting portions 113 are formed, for example, by processing one plate member made of metal. Thus, first plate portion 111, second plate portion 112, and connecting portions 113 are integrally formed from the same member. First plate portion 111, second plate portion 112, and connecting portions 113 therefore have substantially the same surface color.
As illustrated in
The plurality of openings include first opening 120, second openings 121 to 123, etc.
Opening group 101 illustrated in
Two first openings 120 have parts substantially parallel to each other. In detail, two first openings 120 are arranged so that respective long side portions 120a are parallel to each other. The ends of two first openings 120 face each other.
First plate portion 111 is a part surrounded by two first openings 120. First plate portion 111 is substantially rectangular, as illustrated in
Opening group 102 illustrated in
Two second openings 121 each have long side portion 121a and short side portion 121b. Short side portion 121b is formed at the end of long side portion 121a, and is orthogonal to long side portion 121a. Thus, each second opening 121 is a substantially L-shaped slit opening. The length of second opening 121 along the slit direction is less than or equal to half the length of first opening 120 along the slit direction.
Two second openings 121 are arranged so that two long side portions 121a and long side portion 120a of first opening 120 are parallel to each other. Respective long side portions 121a of two second openings 121 lie on a straight line, and connecting portion 113 is provided between long side portions 121a. Each of two short side portions 120b of first opening 120 and short side portion 121b of a corresponding one of two second openings 121 lie on a straight line, and connecting portion 113 is provided between short side portion 120b and short side portion 121b.
Opening group 103 illustrated in
Second opening 122 is a substantially rectangular opening. Second opening 122 is positioned in parallel with long side portion 120a of first opening 120. The length of second opening 122 along the slit direction is less than or equal to half the length of first opening 120 along the slit direction.
Two second openings 123 each have long side portion 123a and short side portion 123b. Short side portion 123b is formed at the end of long side portion 123a, and is orthogonal to long side portion 123a. Thus, each second opening 123 is a substantially L-shaped slit opening. The length of second opening 123 along the slit direction is less than or equal to half the length of first opening 120 along the slit direction.
Second opening 122 and respective long side portions 123a of two second openings 123 lie on a straight line, and connecting portion 113 is provided between each end of second opening 122 and corresponding long side portion 123a. Each of two short side portions 120b of first opening 120 and short side portion 123b of a corresponding one of two second openings 123 lie on a straight line, and connecting portion 113 is provided between short side portion 120b and short side portion 123b.
Opening group 104 illustrated in
One second opening 122 and respective long side portions 123a of two second openings 123 lie on a straight line. The other second opening 122 and respective long side portions 123a of the other two second openings 123 also lie on a straight line. The directions in which these elements are arranged are parallel to each other. In other words, two second openings 122 are arranged in parallel with each other. Connecting portion 113 is provided between second opening 122 and long side portion 123a of each of two second openings 123.
Respective short side portions 123b of two second openings 123 lie on a straight line. Respective short side portions 123b of the other two second openings 123 also lie on a straight line. The directions in which these elements are arranged are parallel to each other. Connecting portion 113 is provided between two short side portions 123b.
Opening group 104 does not include first opening 120, as illustrated in
Opening group 105 illustrated in
Opening group 105 has the shape that combines opening group 102 illustrated in
Opening group 105 does not include first opening 120, as illustrated in
Opening group 106 illustrated in
Opening group 106 has opening group 105 illustrated in
The antenna characteristics of opening groups 101 to 106 mentioned above are described below, with reference to
As illustrated in (a) to (d) in
In opening groups 104 to 106, on the other hand, the SWR is high, and the main lobe strength is low, as illustrated in (e) to (g) in
Opening groups 104 to 106 each do not include first opening 120, as illustrated in
As described above, in the luminaire according to this embodiment, the metal housing has one or more openings in side surface 110, the one or more openings are each a slit opening, and a length of first opening 120 along a slit direction is greater than or equal to substantially half a wavelength corresponding to a frequency of the wireless signal, first opening 120 being at least one of the one or more openings.
Thus, in this embodiment, the metal housing has first opening 120 that functions as a slot antenna to radiate the electric wave from antenna 71 placed in the metal housing to the outside. This ensures the communication function of wireless communication.
Moreover, in this embodiment, the length of first opening 120 along the slit direction is greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency. The electric wave can therefore be efficiently radiated, as can be understood from the comparison between (a) and (e) to (g) in
For example, the metal housing has a plurality of openings in side surface 110, and side surface 110 of the metal housing includes: first plate portion 111 surrounded by the plurality of openings; second plate portion 112 that is a part outside the plurality of openings; and connecting portion 113 that is a part between an end of one of the plurality of openings and an end of another one of the plurality of openings and connects first plate portion 111 and second plate portion 112.
By forming the plurality of openings according to the knockout structure in this way, the electric wave can be radiated more efficiently than in the case where only one first opening 120 is formed, as can be understood from the comparison between (a) and (b) to (d) in
For example, the plurality of openings may include a plurality of first openings 120, and the plurality of first openings 120 may have parts substantially parallel to each other.
In this way, the electric wave can be radiated more efficiently than in the case where only one first opening 120 is formed, as can be understood from the comparison between (a) and (b) in
For example, the plurality of openings may include second opening 121 different from first opening 120, and a length of second opening 121 along a slit direction may be less than or equal to half the length of first opening 120 along the slit direction.
In this way, the electric wave can be radiated more efficiently than in the case where only one first opening 120 is formed, as can be understood from the comparison between (a) and (c) to (d) in
For example, first plate portion 111, second plate portion 112, and connecting portion 113 may have substantially a same surface color.
This makes the openings unnoticeable, which is desirable in aesthetic terms. Besides, in the case where the openings are formed in reflector 40, a reduction in reflection function of reflector 40 can be suppressed.
The following describes a variation of the luminaire according to Embodiment 2, with reference to drawings.
In the luminaire in this variation, a plurality of opening groups are formed in side surfaces of the metal housing.
In the luminaire according to this variation, luminaire body 10 and reflector 40 constitute the metal housing, and two opening groups 101 are formed in side surfaces of the metal housing. In detail, opening group 101 is formed in each of opposite side surfaces 110 and 110a of the metal housing. Two opening groups 101 face each other with antenna 71 in between.
Thus, for example, a plurality of opening groups 101 each including first plate portion 111, connecting portion 113, and a plurality of openings are formed in side surfaces 110 of the metal housing in this variation.
This enables the radiation pattern to be changed.
Although two opening groups 101 are provided in the example illustrated in
For example, the luminaire may further include an insulator in one or more openings.
In the knockout structure, for instance, there is a possibility of erroneous piercing during construction. Such erroneous piercing can be suppressed by providing the insulator.
The following describes a luminaire according to Embodiment 3. While a straight-tube LED lamp is used as an example of the luminaire in Embodiments 1 and 2, a downlight is used as an example in this embodiment.
Luminaire 201 according to this embodiment is, for example, a recessed luminaire such as a downlight that is embedded in ceiling 80 of a house or the like to emit light downward (toward the floor or wall). Luminaire 201 is capable of wireless communication.
As illustrated in
As illustrated in
Each structural member in luminaire 201 is described in detail below.
Light source 202 is a light source for illumination including a light emitting module having a light emitting element, and emits predetermined light. In this embodiment, light source 202 includes a COB light emitting module, or a light emitting module using an SMD LED element.
Luminaire body 210 is a housing which is substantially a truncated cone. A plurality of heat radiation fins 230 protruding outward are provided on the outer peripheral surface of luminaire body 210. Attachment spring 240 is also attached to the outer peripheral surface of luminaire body 210.
Circuit case 220 is a metal housing that contains power circuit 60 and antenna 71. Circuit case 220 is formed, for example, by bending a plate member made of metal such as aluminum.
The detailed structure of circuit case 220 will be described later.
Heat radiation fins 230 are fins for radiating heat generated when light source 202 emits light, to the outside. For example, heat radiation fins 230 are formed integrally with luminaire body 210.
Attachment spring 240 is fixed to the outer peripheral surface of luminaire body 210, and is biased outward. Attachment spring 240 is used to install luminaire 201 (luminaire body 210) into embedding hole 81.
Attachment portion 250 is connected to a cable (not illustrated) that is connected to system power (utility power) which is the supplier of AC power. Attachment portion 250 feeds AC power obtained via the cable, to power circuit 60 in circuit case 220 via cable 260. Attachment portion 250 is provided at one end of circuit case 220 in the longitudinal direction.
Cable 260 is a cable for supplying the AC power received by attachment portion 250 to power circuit 60 in circuit case 220. Cable 261 is a cable for supplying the power from power circuit 60 in circuit case 220 to light source 202 in luminaire body 210.
Circuit case 220 according to this embodiment is described in detail below.
Circuit case 220 according to this embodiment is a polyhedral metal housing, and has upper cover 221 and lower cover 222 that are combined so as to create a gap. By combining upper cover 221 and lower cover 222, openings 223 and 224 are formed in circuit case 220, as illustrated in
Upper cover 221 and lower cover 222 are an example of a metal structure. Upper cover 221 and lower cover 222 are each formed by processing a plate member made of metal. Upper cover 221 and lower cover 222 each have a plurality of substantially rectangular surfaces.
Upper cover 221 has opening 225. Opening 225 is a gap formed in upper cover 221.
Opening 225 is formed along a side of a substantially rectangular surface. For example, upper cover 221 has surfaces 221a to 221c, as illustrated in
As illustrated in
Moreover, opening 225 connects to opening 224. In other words, opening 225 forms one continuous opening together with opening 224, and this opening extends over three continuous sides of the polyhedron (i.e. three sides of surface 221c). The length of the opening is greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency.
The radiation pattern of the electric wave can be changed by providing the plurality of openings 223 to 225 in circuit case 220 in the above-mentioned manner.
The following describes how the radiation pattern changes according to the arrangement of openings in the metal housing, with reference to
Metal housing 300 illustrated in 16A is a metal housing which models circuit case 220 according to this embodiment. Metal housing 300 is a polyhedron, and has surfaces 301 to 305. Surfaces 304 and 305 are parallel to each other, and perpendicular to surfaces 301 to 303, as illustrated in
Metal housing 300 has two openings 310 and 311. Two openings 310 and 311 are parallel to each other.
Opening 310 is formed on sides of surface 304. In detail, opening 310 is formed between surface 304 and each of surfaces 301 to 303. Thus, opening 310 extends over three continuous sides of surface 304.
Opening 311 is formed on sides of surface 305. In detail, opening 311 is formed between surface 305 and each of surfaces 301 to 303. Thus, opening 311 extends over three continuous sides of surface 305.
Opening 330 is formed on a side of surface 304. In detail, opening 330 is formed between surface 303 and surface 304.
Opening 331 is formed on a side of surface 305. In detail, opening 331 is formed between surface 303 and surface 305.
In
The radiation pattern of metal housing 300 has wide directivity on the bottom side in both of the XZ plane and the YZ plane, as illustrated in
On the other hand, the radiation pattern of metal housing 320 has null point on the bottom side in both of the XZ plane and the YZ plane, as illustrated in
As described above, in this embodiment, the radiation pattern of the electric wave radiated from the metal housing can be changed according to the arrangement of openings in the metal housing (i.e. circuit case 220). Here, more excellent radiation pattern characteristics are attained in the case where the opening extends over two or more continuous sides of the polyhedron as in metal housing 300 illustrated in
The following describes the relationship between the opening width of openings and the radiation pattern, with reference to
The opening width of an opening is the width of a slit opening in the direction orthogonal to the slit direction. For example, in the case where the opening is substantially rectangular in shape, the opening width is the width in the transverse direction.
For example, in the XZ plane, the main lobe strength is −23.4 dB when the opening width is 0.5 mm, and −11.6 dB when the opening width is 1.0 mm. In the YZ plane, on the other hand, the main lobe strength is −16.7 dB when the opening width is 0.5 mm, and −30.5 dB when the opening width is 1.0 mm.
Thus, the radiation pattern differs significantly when the opening width is different. This indicates that constant opening width of openings contributes to more stable wireless communication. For example, the opening width of the openings can be maintained by providing, between the openings, an insulator for maintaining the opening width of the openings.
As an example, opening 223 illustrated in
Providing an insulator in opening 223, however, allows the opening width of opening 223 to be maintained. The insulator is made of an insulating resin material as an example. The insulator can be provided in opening 223, for instance, by applying the insulating resin material and curing it by light irradiation or the like.
The insulator provided in opening 223 may be any insulator. For example, an insulating plate member may be pinched in opening 223.
The following describes the relationship between the distance between a plurality of openings and the radiation pattern, with reference to
Metal housing 400 illustrated in
Openings 410 and 411 and openings 430 and 431 have the same length and width. In detail, openings 410 and 411 and openings 430 and 431 have a length greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency. Openings 410 and 411 and openings 430 and 431 are formed in surface 303 which corresponds to the bottom surface of a corresponding one of metal housings 400 and 420.
Openings 410 and 411 are at distance D1 from each other, as illustrated in
Distance D1 is a length greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency. Distance D2 is a length less than substantially half the wavelength corresponding to the wireless signal frequency. Thus, distance D1 is longer than distance D2.
The strength of the electric wave from metal housing 400 is greater than the strength of the electric wave from metal housing 420, as illustrated in
As described above, in luminaire 201 according to this embodiment, circuit case 220 (the metal housing) includes two or more metal structures that are combined with each other to create a gap, openings 224 and 225 are each the gap, and a length of openings 224 and 225 is greater than or equal to substantially half a wavelength corresponding to a frequency of the wireless signal.
Thus, the opening of the length greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency is provided. This enables efficient radiation of the electric wave, and improves the communication quality of wireless communication. Moreover, since the gap created by combining the two or more metal structures is used as the opening, there is no need to form the opening in the metal structure. A reduction in the number of manufacturing steps contributes to lower cost.
For example, circuit case 220 is a polyhedron, and openings 224 and 225 are each positioned on a side of the polyhedron.
In this way, the radiation pattern can be changed according to the position of the opening. In other words, the radiation pattern can be changed according to on which side of the polyhedron the opening is provided. Hence, an appropriate radiation pattern can be formed depending on, for example, the installation location of luminaire 201.
For example, opening 225 extends over two or more continuous sides of the polyhedron.
It is desirable to reduce the size of circuit case 220 (metal housing) in which power circuit 60 is contained, in order to reduce the size of luminaire 201. Reducing the size of circuit case 220, however, makes it difficult to form an opening with a necessary length.
In this embodiment, on the other hand, the opening extends over two or more sides of the polyhedron, and so is guaranteed to have a length greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency. This enables efficient radiation of the electric wave, and improves the communication quality of wireless communication.
For example, circuit case 220 has a plurality of openings 225 that are parallel to each other.
This enables efficient radiation of the electric wave, and improves the communication quality of wireless communication.
For example, a distance between the plurality of openings 225 parallel to each other is greater than or equal to substantially half the wavelength corresponding to the frequency of the wireless signal.
Setting the distance between the plurality of openings to be greater than or equal to substantially half the wavelength corresponding to the wireless signal frequency enables efficient radiation of the electric wave, and improves the communication quality of wireless communication.
For example, the luminaire may further include an insulator provided in opening 225 to maintain an opening width of opening 225.
The opening width of the opening can be maintained in this way, as a result of which stable wireless communication can be performed.
Although this embodiment describes the type of downlight in which luminaire body 210 and circuit case 220 are separated physically and connected by cable 261 as illustrated in
Circuit case 220A is a metal housing which is substantially a rectangular parallelepiped, and contains power circuit 60 and wireless module 70 (not illustrated). Circuit case 220A has openings 221A and 222A. The openings are shown by thick lines (thick solid line or thick dotted line) in
Openings 221A and 222A are provided at an end of substantially rectangular parallelepiped circuit case 220A in the longitudinal direction. Openings 221A and 222A are each a slit opening extending over two sides of circuit case 220A. Openings 221A and 222A are parallel to each other.
With this structure, too, circuit case 220A functions as a slot antenna to enable wireless communication.
Although Embodiment 3 describes an example where the luminaire is a downlight, the luminaire is not limited to such. For example, the luminaire may be a straight-tube LED lamp as described in Embodiment 1.
The following describes variations of Embodiment 3, with reference to
Luminaire 500 illustrated in
Luminaire body 510 has openings 511 to 514, instead of opening 11. In this variation, wireless module 70 is, for example, contained in circuit case 550. Circuit case 550 accordingly has openings 551 to 554. The openings are shown by thick lines (thick solid line or thick dotted line) in
Openings 511 and 512 are formed at one end of long luminaire body 510 in the longitudinal direction. Openings 511 and 512 are each an L-shaped slit opening extending over two sides of luminaire body 510. Openings 511 and 512 are parallel to each other.
Openings 513 and 514 are formed at the other end of long luminaire body 510 in the longitudinal direction. Openings 513 and 514 are each an L-shaped slit opening extending over two sides of luminaire body 510. Openings 513 and 514 are parallel to each other.
Openings 551 and 552 are formed at one end of substantially rectangular parallelepiped circuit case 550 in the longitudinal direction. Openings 551 and 552 are each a slit opening extending over two sides of circuit case 550. Openings 551 and 552 are parallel to each other.
Openings 553 and 554 are formed at the other end of substantially rectangular parallelepiped circuit case 550 in the longitudinal direction. Openings 553 and 554 are each a slit opening extending over two sides of circuit case 550. Openings 553 and 554 are parallel to each other.
With this structure, too, circuit case 550 and luminaire body 510 each function as a slot antenna to enable wireless communication.
Luminaire 500a illustrated in
Luminaire body 510a has openings 511a to 514a, instead of opening 11. In this variation, wireless module 70 is, for example, contained in circuit case 550. The openings are shown by thick lines (thick solid line or thick dotted line) in
Openings 511a and 512a are formed in side surfaces near one end of long luminaire body 510a in the longitudinal direction. Openings 511a and 512a are each a substantially rectangular slit opening formed in luminaire body 510a. Openings 511a and 512a are parallel to each other.
Openings 513a and 514a are formed in side surfaces near the other end of long luminaire body 510a in the longitudinal direction. Openings 513a and 514a are each a substantially rectangular slit opening formed in luminaire body 510a. Openings 513a and 514a are parallel to each other.
With this structure, too, circuit case 550 and luminaire body 510a each function as a slot antenna to enable wireless communication.
Luminaire 500b illustrated in
Luminaire body 510b has openings 511b and 512b, instead of opening 11. In this variation, wireless module 70 is, for example, contained in circuit case 550. The openings are shown by thick lines (thick solid line or thick dotted line) in
Openings 511b and 512b are formed in side surfaces at the center of long luminaire body 510b in the longitudinal direction. Openings 511b and 512b are each a substantially rectangular slit opening formed on a side of the corresponding side surface of luminaire body 510b. Openings 511b and 512b are parallel to each other.
With this structure, too, circuit case 550 and luminaire body 510b each function as a slot antenna to enable wireless communication.
Although foregoing Variations 1 to 3 describe an example where the luminaire includes a cylindrical straight-tube LED lamp having a feeding base and a non-feeding base as light source 2, this is not a limitation. This variation describes a luminaire that includes a line light source having a half-cylindrical cover.
Luminaire 600 includes light source 602, luminaire body 610, connectors 620 and 630, power circuit 60, and wireless module 70.
Light source 602 includes a long LED module and a long translucent cover for covering the LED module. The LED module is, for example, a COB light emitting module in which an LED chip is directly mounted on a board.
Luminaire body 610 is an example of a metal structure. Luminaire body 610 is formed, for example, by bending a plate member made of metal such as aluminum to have opening 611 on the lower side. While luminaire body 510 in Variation 1 and the like is substantially a rectangular parallelepiped, luminaire body 610 in this variation is a flat and long polyhedron. In detail, luminaire body 610 is convex, and has opening 611 in the convex portion.
Luminaire body 610 is connected to connector 620. Connector 620 is a connector for feeding power to light source 602, and is connected to connector 630 to feed power from an external power source (e.g. utility power) to light source 602. In detail, connector 630 is connected to power circuit 60. Power circuit 60 converts power supplied via connectors 620 and 630 and supplies the converted power to light source 602.
Power circuit 60 and wireless module 70 are positioned on the opposite side to the cover of the LED module. Thus, power circuit 60 and wireless module 70 are contained in luminaire body 610 through opening 611 of luminaire body 610 when luminaire body 610 and light source 602 are combined.
Luminaire body 610 has openings 612 and 613.
Openings 612 and 613 are arranged along opening 611 of long luminaire body 610. Openings 612 and 613 are each a substantially rectangular slit opening formed on a side of a side surface of luminaire body 610. Openings 612 and 613 are parallel to each other. Openings 612 and 613 remain open even when luminaire body 610 and light source 602 are combined, and so can radiate the electric wave from wireless module 70.
With this structure, too, luminaire body 610 functions as a slot antenna to enable wireless communication.
Although Variation 4 describes an example where luminaire body 610 is convex and light source 602 is outside luminaire body 610, this is not a limitation. This variation describes a luminaire in which light source 602 is contained in luminaire body 610.
Luminaire 700 includes light source 602, luminaire body 710, connectors 620 and 630, power circuit 60, and wireless module 70.
Luminaire body 710 is an example of a metal structure. Luminaire body 710 is formed, for example, by bending a plate member made of metal such as aluminum to have opening 711 on the lower side. Luminaire body 710 is a flat and long polyhedron. In detail, luminaire body 710 is concave, and has opening 711 in the concave portion. Surfaces 712 and 713 forming the concave portion are, for example, reflection surfaces.
Power circuit 60 and wireless module 70 are contained in luminaire body 710 through opening 711 of luminaire body 710 when luminaire body 710 and light source 602 are combined, as in Variation 4.
Luminaire body 710 has openings 714 and 715.
Openings 714 and 715 are arranged along opening 711 of long luminaire body 710. Openings 714 and 715 are each a substantially rectangular slit opening formed on a side of a corresponding one of surfaces 712 and 713 of luminaire body 710. Openings 714 and 715 are parallel to each other. Openings 714 and 715 remain open even when luminaire body 710 and light source 602 are combined, and so can radiate the electric wave from wireless module 70.
With this structure, too, luminaire body 710 functions as a slot antenna to enable wireless communication.
Although the luminaire according to the present disclosure has been described by way of the foregoing embodiments and their variations, the present disclosure is not limited to the foregoing embodiments.
Although the foregoing embodiments describe an example where the antenna is mounted on the printed wiring board, this is not a limitation. The antenna may be a single antenna or the like.
Although the foregoing embodiments describe an example where the metal housing having one or more openings is a polyhedron such as substantially a rectangular parallelepiped, this is not a limitation. The metal housing may have a curved surface. For example, the metal housing may be substantially a cylinder or substantially a truncated cone.
Embodiments 2 and 3 and their variations may be realized independently of Embodiment 1. In detail, Embodiments 2 and 3 and their variations may be realized each as a structure that does not include the matter described in the independent claim representing a superordinate concept. For example, in Embodiments 2 and 3, etc., the antenna and the opening may be arranged without substantial coincidence between the polarization plane of the electric wave most strongly radiated from the antenna and the polarization plane of the electric wave most strongly radiated from the opening.
Other variations obtained by applying various changes conceivable by a person skilled in the art to the embodiments and any combinations of the structural elements and functions in the embodiments without departing from the scope of the present disclosure are also included in the present disclosure.
While the foregoing has described what are considered to be the best mode and/or other examples, it is understood that various modifications may be made therein and that the subject matter disclosed herein may be implemented in various forms and examples, and that they may be applied in numerous applications, only some of which have been described herein. It is intended by the following claims to claim any and all modifications and variations that fall within the true scope of the present teachings.
Number | Date | Country | Kind |
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2014-181664 | Sep 2014 | JP | national |