[0001] The invention relates to a translucent antenna foil mounted on an optical element
of a device, with none or at most minor negative effect on a respective optical light
path desired for the respective optical element.
[0002] Currently known antennas in use in luminaires or other devices with optical elements
are usually positioned inside a respective housing of a luminaire. However with this
structural setup, especially with devices having metal housings signal communication
from and towards such antennas is negatively affected.
[0003] Some other forms of antennas are also known, whereas hereby these antennas are either
fixedly integrated inside the respective optical element or are inflexible and stiff
extra components that mounted inside of a respective housing of a device. However,
this arrangement is often regarded as disadvantage with regard to a uniform light
distribution.
[0004] The
EP 3 320 581 B1 deals with such an extra antenna device being mounted cantered inside a luminaire
on a printed circuit board. In
US 2019/0323683 A1 an antenna is described that is fixedly connected to a respective flexible printed
circuit board, whereas the antenna is disposed on a surface of a light guide plate
of a light-emitting device, and the light-emitting device emits light on the basis
of identification information obtained through communications via antenna. The
US 2009/0047900 A1 describes a repeater system that is designed to amplify mobile radio communications,
particularly through metallised window panes, whereas hereby an outside and inside
antenna are required that are connected, whereas the inside antenna is integrated
inside the respective window and retransmits signals received from the outside antenna.
However, these known antennas are not suitable for applications in which an antenna
is to be flexibly arranged in or on optical elements of any shape.
[0005] Thus, the invention is concerned with the task of providing a flexible antenna for
flexible use in optical elements applications. This task is solved by the translucent
antenna foil comprising an antenna, for use in a device having an optical element
according to independent claim 1. The invention is defined in the independent claims.
Additional features of the invention are provided in the respective dependent claims.
[0006] According to the invention the translucent antenna foil comprising an antenna, for
use in a device having an optical element, is mountable on or in the optical element
of the respective device, and has an antenna portion and a feeder line portion. Hereby,
an antenna conductor of the antenna for emitting and receiving signals is positioned
in the antenna portion, and the feeder line portion includes a connector having respective
contacts for coupling the antenna to a complementary connector on a circuit board
of the device, and a connecting portion connecting the antenna conductor and the connector.
Furthermore, both the antenna portion and the feeder line portion are substantially
translucent.
[0007] With this translucent antenna foil an utmost flexible antenna application is achieved,
as the antenna is easily mounted in or on a respective optical element of a device,
being adaptive to the respective shape of the optical element due to its foil character.
With the antenna portion being translucent, unwanted light distortion is minimized,
whereas this also applies for the feeder line portion also being substantially translucent.
Thus, the translucent antenna foil allows for a positioning of the antenna in convenient
positions of the respective device, minimizing influence of other components of the
device on the signal communication towards and from the antenna.
[0008] Furthermore, besides the translucent antenna foil itself also a kit consisting of
the translucent antenna foil and a respective optical element on which the antenna
foil is mounted is disclosed herein. Features relating to the antenna foil and/or
the optical element thus are also valid for the combined assembly.
[0009] Moreover, a device is proposed herein, wherein the device comprises an optical element,
a circuit board and a housing, whereas the optical element and the circuit board are
arranged on an inside of the device. The device further comprises a light emitting
element, such as an LED, or a light receiving element, such as a sensor element, or
respectively multiple thereof wherein the device further comprises the antenna foil
according to any one of the herein disclosed embodiments of the translucent antenna
foil. Hereby, the optical element is made of plastic and/or glass and the antenna
foil is mounted on and/or in the optical element. Moreover, the antenna foil is coupled
via its connector to the circuit board. With the respective antenna foil in use, the
user of the device may not detect the foil per se, with its respective translucent
characteristics, increasing the devices aesthetics.
[0010] The one or multiple light emitting elements may be positioned on an LED-module (or
multiple LED-modules), whereas it is also conceivable that respectively one or multiple
OLEDs are used as the light emitting element(s), or the like.
[0011] The such configured device benefits from the advantages of the translucent antenna
foil, as the light emission or light absorption (respectively light intake) of the
device is not influenced in an unwanted way. Hereby - depending on the specific configuration
of the translucent antenna foil and the respective use scenario - the translucent
antenna foil can also aid in light manipulation, e.g., when a light homogenization
is desired via a diffusing characteristic of the translucent antenna foil, or the
like. Furthermore, a beneficial signal transmission towards and from the antenna of
the device is achieved, as the antenna is arranged on or in the optical element, and
not, e.g., on a printed circuit board of the device or inside the (often metallic)
housing of the device, reducing the influence of jamming sources.
[0012] Optionally the antenna foil comprises an electrically conductive middle layer and
two laminated foil layers, sandwiching the middle layer. Hereby the electrically conductive
middle layer comprises the antenna conductor. With such a configuration, the conductive
middle layer, respectively the antenna, is protected against outside influences. The
two laminated foil layers hereby provide a continuous insulation up to the plug (i.e.,
the connector) due to the two foil layers being laminated on both sides encapsulating
the middle layer. This results in an utmost durable, flexibly applicable antenna foil.
[0013] Preferably, both the antenna portion and the feeder line portion are formed by the
two laminated foil layers, and the conductive middle layer arranged between the two
foil layers. With this configuration both the feeder line portion and the antenna
portion are equally durable yet flexible, and furthermore the middle layer is particularly
protected from outside influences. Also, preferably, a non-conductive filler material,
for example an insulator, may be provided in the middle layer between adjacent segments
of the antenna conductor and further preferred also in edge regions of the antenna
foil. Hereby an improved electric isolation of different segments of the antenna is
achieved. With the insulation in the edge regions a further improved separation from
outside influences is achieved, whereas the non-conductive filler is ideally not present
at the end face of the connector, such that an ideal electrical coupling of the plug
with the respective counterpart is possible.
[0014] Optionally in an end region of the feeder line portion only one of the two laminated
foil layers, is present, and thus in this end region the conductive middle layer is
uncovered forming the contacts of the connector of the feeder line portion. Via this
implementation an easy but effective connection of the antenna with the device is
achievable. Preferably in the section of the uncovered middle layer a reinforcing
layer is provided on top of the only foil layer. Hereby the feeder line portion and
in particular the connector is reinforced, forming it more durable and easy to connect
to the respective opposite connection mean of the device. Moreover it may be desired
that in the section of the uncovered middle layer the uncovered segments of the antenna
conductor are provided with a metal print, preferably with a silver print and/or a
gold print and/or a copper print and/or by plasma metallization, forming the contacts
of the connector of the feeder line portion. This improves signal transmission of
the antenna due to reduction of losses at the connector interface between the antenna
foil and the device by the selected metal material and protects the conductive layer.
[0015] Optionally the antenna conductor comprises copper. This improves antenna characteristics
of the antenna foil, while simultaneously ensuring a flexible but still durable foil.
Hence, it is preferred that the antenna foil is made flexible and in particular reversibly
bendable. This ensures applicability of the foil in various scenarios and further
ensures different application scenarios over its lifetime.
[0016] Optionally the antenna foil is substantially transparent and preferably has a degree
of transparency of at least 90%. This allows the antenna to be positioned on optical
elements where direct and ultimately lossless light transmittal is important.
[0017] Optionally the antenna foil itself has a light-diffusing effect, and preferably is
opaque. With this implementation, the foil itself may be arranged on an optical element
that is a diffusor, and hereby may also improve diffusing characteristics of the optical
element via synergy. The antenna foil hereby contributes to the desired influence
on the optical path of the respective regarded emitted or received light. Further,
preferably the antenna conductor is such arranged within the middle layer that it
contributes to the diffusion effect. The arrangement of the various antenna segments
of the antenna conductor can be aligned such that a respective diffusing effect is
achieved by the foil.
[0018] Optionally the antenna foil has, at least in the antenna portion, an adhesive layer
which is arranged on one of the foil layers. This allows for an utmost easy and flexible
positioning on or in an optical element. Preferably, the adhesive layer is integrally
formed by one of the foil layers. With this implementation production of the antenna
foil is facilitated and furthermore the antenna foil is formed as slim as possible,
while maintaining preferred antenna characteristics and flexible usage of the foil.
[0019] Optionally the antenna conductor forms a wire mesh, which is formed, e.g., in a flat
coil shape, wherein further preferably the wire mesh is designed for transmitting
and/or receiving NFC signals or other RFID signals. The foil may also be designed
to transmit and receive Sub-GHz, 5 GHz frequency band signals, 2.4 GHz frequency band
signals, Zig-Bee signals, and/or 5G signals or RF signals with another frequency.
The such formed antenna foil is adapted to the respective usage scenario and an optimal
signal transmission and receival is obtained via the respective specific antenna wire
mesh arrangement.
[0020] Optionally with regard to the device, the optical element together with the light
emitting or light receiving element, forms an effective optical field EOF of the device,
wherein at the antenna portion of the antenna foil is arranged in the device such
that only components of the device made of plastic and/or glass are arranged within
the effective optical field EOF between an outside O of the device and the antenna
portion. Hereby it is achieved due to the specific arrangement of components that
no metal is arranged in-between the outside area and the antenna foil, such that signal
transmission and receival can be performed without losses due to interfering objects.
Thus, the so formed device has a further increased accessibility for communication
with a user's operating device, resulting in an easy and comfortable communication
and thus maintenance of the device due to the beneficial arrangement of the antenna
foil.
[0021] Optionally with regard to the device, the antenna portion of the antenna foil is
arranged on a side of the optical element facing the light emitting or light receiving
element, or wherein the antenna portion of the antenna foil is disposed inside the
optical element itself. Depending on the present operation scenario either configuration
may be regarded as beneficial, whereas the disposal inside the optical element further
protects the antenna foil, and the arrangement on an outer surface of the optical
element further facilitates setup of the device.
[0022] Optionally with regard to the device, the antenna foil is coupled to the optical
element by means of an adhesive element, for example by means of an adhesive layer
arranged on an outer surface layer of one laminated foil layer, of the antenna foil,
or wherein the antenna foil is coupled to the optical element by means of holding
elements and/or guide elements, which are preferably formed by the optical element
itself. While the coupling via an adhesive element further eases setup and provides
a secure mounting, repositioning the antenna foil may be more complicated than the
positioning via the structural elements for holding and/or guiding the foil.
[0023] Optionally with regard to the device, the circuit board of the device comprises control
electronics components for controlling an antenna, the control electronics components
also comprising the complementary connector to which the antenna foil is coupled via
its connector. With the respective circuit board, onboard control of the antenna directly
via the device is possible. Preferably, the circuit board of the device is a control
electronics board for controlling an antenna. Thus, the antenna of the antenna foil
is controlled via a distinct circuit board. Further preferably, the complementary
connector is a zero insertion force, ZIF, connector. This eases assembly of the device
and further increases lifespan of the antenna foil, as no force is required during
connection of the connector with the complementary connector.
[0024] In a preferred embodiment the device is a luminaire, whereas the luminaire has a
light source board having a plurality of light sources, e.g., LEDs, and wherein the
optical element transmits light being emitted from the light sources. Preferably,
the light guide is a diffuser arranged subsequent to the light source board in the
light emitting direction of the light sources. Hereby the antenna foil is arranged
on or in the optical element and may therefore be arranged in-between a light emission
surface of the luminaire and the light sources of the luminaire, without affecting
light transmission in an unwanted manner. With the optical element being a diffusor,
the antenna foil is preferably also designed with a diffusing characteristic improving
diffusion of the luminaire.
[0025] Optionally with regard to the luminaire as the device, the circuit board of the luminaire
is the control electronics board that is arranged separately from the light source
board inside the luminaire. With this setup the space within the luminaire can be
ideally used, and the control electronics board with the components for controlling
the antenna of the antenna foil are separated from other circuit boards (such as the
light source board) such that electromagnetic interference is minimized. Alternatively
the light source board of the luminaire also comprises control electronics components
for controlling an antenna, the control electronics components also comprising the
complementary connector to which the antenna foil is coupled via its connector, whereas
the control electronics components are positioned on a side of the light source board
that is opposite to the side on which the light sources are mounted. With this implementation
a single printed circuit board is required within the luminaire for simultaneously
achieving illumination and a signal transmission and receival.
[0026] In another embodiment the device is a sensor, whereas the sensor has a sensor board
having at least one sensor element, wherein the optical element forms a light entry
surface of the sensor, and transmits light towards the sensor element. Hereby, the
available space of the sensor is used very efficient, wherein a convenient communication
mean is provided with the antenna of the antenna foil. The control electronics components
for controlling the antenna of the antenna foil can either be provided on the same
circuit board as the sensor element of the sensor, or can also be provided on a separate
circuit board, as previously discussed with regard to the other embodiment of the
device being a luminaire. Preferably the sensor is a passive infrared, PIR, motion
detector, an infrared, IR, sensor, and/or a light sensor.
[0027] The invention is explained in detail below with reference to examples of embodiments
and with reference to the drawing. The figures show:
- Figure 1
- Schematic cross-sectional illustration of an exemplary embodiment of a device comprising
an exemplary embodiment of the antenna foil being mounted on the optical element of
the device;
- Figure 2
- Schematic cross-sectional illustration of an exemplary embodiment of a device being
a luminaire with an exemplary embodiment of the antenna foil being mounted on the
diffusor inside the luminaire;
- Figure 3
- Schematic illustration of an exemplary embodiment of an antenna foil in a top view;
- Figure 4
- Schematic cross-sectional illustration of the exemplary embodiment of the antenna
foil known from Figure 3.
[0028] Figure 1 shows a schematic illustration of a device 10, which may be a sensor 12
or a luminaire 11, or any other device where an optical element 200 is present and
an easy and interference-free communication via the antenna foil 100 is desired. An
exemplary illustration of the antenna foil 100 itself is shown in Figures 3 and 4.
Figure 2 shows an exemplary embodiment of the device 10 being a luminaire 11.
[0029] The features described with regard to Figure 1 are also valid in their generality
with regard to the implementation of Figure 2. The same applies with regard to the
features of the luminaire 11 described explicitly with regard to Figure 2 with regard
to the general device 10. The embodiments of an antenna foil 100 shown and described
in Figures 3 and 4 are each individually transferable to the device 10 known from
Figures 1 and 2 or the antenna foil 100 known therefrom.
[0030] Figures 1 and 2 each show a device 10 comprising an optical element 200, at least
one circuit board 300, 500 and a housing 600, 700, wherein the optical element 200
and the circuit board 300, 500 are arranged on an inside I of the device 10. The device
10 further comprises an antenna foil 100, which is connected to (at least) one of
the circuit boards 300, 500 of the device 10. In the shown embodiments the antenna
foil 100 is each directly linked to a control electronics board 500.
[0031] As shown in Figure 1 the antenna foil 100 is positioned in an inside I of the device
10, whereby it is hereby mounted on an inside surface of the optical element 200.
The antenna foil 100, respectively the antenna portion 110 of the antenna foil 100
is thus arranged in-between the optical element 200 and a circuit board 300 on which
a light receiving element 320, such as a sensor 320, or a light emitting element 310,
such as an LED 310 or LED module 310, is mounted. The feeder line portion 120 of the
antenna foil 100 juts from the optical element 200 further inside the device 10, respectively
further inside the housing 700 of the device 10. Hereby the antenna foil 100, respectively
its feeder line portion 120, may jut through a through hole 420 of the carrier element
400 (or depending on the size of the circuit board 300, also a through a respective
trough hole of the circuit board 300), to further reach inside the device 10 where
control electronics components 510 for controlling the antenna are positioned. The
connection with these control electronics components 510 may be realized via a complementary
connector 520 that is complementary designed to the connector 123 of the antenna foil
100. In the shown embodiment a control electronics board 500 is present inside the
device 10, whereas the control electronics board 500 is a printed circuit board, PCB,
on which the control electronics components 510 and the complementary connector 520
are positioned.
[0032] The control electronics components 510 are hereby configured to receive the signals,
which obtained by the antenna of the antenna foil 100 and provided via the connection
of connectors 520 and 123, and evaluate these signals. Based on the message included
in the signals the controller of the control electronics components 510 may control
the light emission and/or light receiving element 310, 320, and/or may also send a
respective answer signal via the antenna of the antenna foil 100. The internal communication
between the components of the device 10 may hereby be realized via a respective internal
bus interface 900.
[0033] Onside the circuit board 300, which depending on the implementation of the device
10, may be a light source board 300 (with the device 10 being a luminaire 11) or a
sensor board 300 (with the device 10 being a sensor 12) or the like, a light emitting
or light receiving element 310, 320 is positioned. The light emitting or light receiving
element 310, 320 hereby equally have a respective effective optical field EOF whereas
the respectively present optical element 200 may also influence the effective optical
field EOF depending on its light guiding characteristics. Hereby the optical element
200 is made of plastic and/or glass for optimal desired light guidance. Thus, with
the influences of the optical element 200 and the antenna foil 100 the device 10 itself
has an effective optical field EOF, which describes an area of the device 10, which
is relevant for the respective light emitting or light receiving element 310, 320.
An exemplary effective optical field EOF of the respective device 10 is schematically
indicated in Figures 1 and 2 by the enclosed area of the boarder lines and the dashed
lines.
[0034] The carrier element 400 is positioned inside I of the device 10 and is preferably
connected to the housing 400 of the device 10. Depending on the implementation of
the device 10 the device 10 may also comprise a translucent (or even transparent)
cover 600 that closes the housing in light emission and/or light receiving direction
of the respective light emitting or light receiving element 310, 320. The cover 600
provides a certain ingress protection, forming the device 10 more durable against
dust, moisture and/or water. The housing 700 together with the cover 600 boarder the
device 10 and distinguishes in an inside I of the device 10 and an outside O of the
device 10.
[0035] However, if no cover 600 is present, the optical element 200 itself may provide at
least to some degree protection to the electronic components of the device 10, and
substitutes the cover 600. The optical element 200 is also connected to the carrier
element 400, whereas as shown in Figure 1 individual connecting elements 800 may be
used for reversible attachment of the optical element 200. These connecting elements
800 may be formed by screws, pins, a latch element or the like.
[0036] A user being at an outside O of the device 10 operates a certain device that is equipped
with a wireless communication module. Hereby it is realized that the wireless communication
module of the user device matches a signal transmission technology supported by the
antenna of the antenna foil 100, such that the user device and the device 10 are able
to communicate with each other.
[0037] With the arrangement of the antenna foil 100 being placed inside or onside the optical
element 200 it is achieved that only a minimum number of elements is arranged between
the antenna foil 100 and the respective user device of a user. No interference objects,
in particular made out of metal are arranged in-between the antenna foil 100 on the
inside I of the device 10 and the outside O of the device such that a particular favourable
signal transmission is possible. As shown in Figure 1 no metal elements is arranged
in-between, whereas the influence of the material of the housing of the device 10
is reduced to a minimum, and indeed can be disregarded, due to the specific arrangement
and layout of the antenna foil 100.
[0038] The effective optical field EOF of a device 10 is usually not only the area being
illuminated (luminaire 11) or observed (sensor 12), but also the area where a user
device is located for communication with the device 10 via its antenna. In particular,
in the presented embodiment, with the arrangement of the antenna foil 100 it is achieved
that the antenna portion 110 of the antenna foil 100 is positioned inside the device
10 such that only components of the device 10 made of plastic and/or glass are arranged
within the effective optical field EOF between the outside O of the device 10 and
the antenna portion 110. This vastly reduces interferences and therefore boosts signal
transmission quality and therefore also increases efficiency of the device 10.
[0039] In an alternative to what is shown in Figure 1 it is also conceivable that the control
electronics board 500 is mounted on a backside of the carrier element 400 - such that
the control electronics board 500 is mounted on the opposite side of the carrier element
400 with regard to the light source board 300, or the respectively the sensor board
300. Moreover, it is also thinkable, that the circuit board 300 is mounted on a spacing
410 allowing the electronics components 510 and the complementary connector 520 being
positioned on a backside of the circuit board 300 that is opposite to the side of
the circuit board 300 having the light emitting or light receiving element 310, 320.
With this implementation only one circuit board is necessary and the available space
is utmost efficiently used.
[0040] As further shown the circuit boards 300, 500 can also be connected to an external
power and/or communication line 1000 via a respective interface 900 that comprises
respective ports on each thereto connected circuit board 300, 500. Hereby the control
electronics board 500 and/or the light source board 300 (respectively the sensor board
300) are fed with electrical energy and/or with commands regarding their operation.
Further, the electrical components may also communicate received and/or gathered data
with external components via the interface 900 and the respective line 1000.
[0041] Figure 2 shows a specific implementation of the device 10 being a luminaire 11, with
light emitting elements 310 being LEDs 310. Hereby the cover 600 is coupled via snap-fit
with the housing 700 forming a durable enclosure against ingress of dust, moisture
or water. Hereby a respective coupling 650 between the housing 700 and the cover 600
is realized by both components. As indicated the coupling 650 may also comprise a
gasket.
[0042] On the inside I of the shown device 10 (respectively the luminaire 11) the carrier
element 400 is arranged, whereas the optical element 200 is coupled thereto as well
as the control electronics board 500. Between the optical element 200 and the carrier
element 400 a containment is present, in which the circuit board 300 is arranged.
On the side of the optical element 200 facing the circuit board 300 the antenna foil
100 is mounted. Hereby the circuit board 300 - which in the shown embodiment is a
light source board 300 - is attached to the carrier element 400 via spacing elements
410, such that the circuit board 300 is arranged on the inside of the containment
on a level of the optical element 200 that is equipped with the antenna foil 100.
Thus in the presented embodiment the circuit board 300 is sphered by the antenna foil
100. This results in a homogenous light emission (respectively a uniform light receival)
of the device 10, as the antenna foil 100 is attached to the optical element 200 in
the respective section over the relevant height.
[0043] As shown in Figure 2 the feeder line portion 120 is arranged outside the effective
optical field EOF such that the feeder line portion 120 does not necessarily have
the same light effecting characteristic as the antenna portion 110. However, in scenarios,
where the feeder line portion 120 indeed is arranged in the effective optical field
EOF - see, e.g., Figure 1 - a respectively adapted configuration is preferred.
[0044] In the shown embodiment the optical element 200 is a diffusor. Hereby different scenarios
are conceivable, whereas it is possible that the antenna foil 100 is configured transparent,
and in the alternative that the antenna foil 100 itself comprises light diffusing
characteristics, and thus supports light diffusion of the optical element 200. If
however a clean transparent optical element 200 is desired, the antenna foil 100 is
ultimately also configured transparent.
[0045] The diffusor (i.e., the optical element 200) is hereby arranged subsequent to the
light source board 300 in the light emitting direction of the light sources 310.
[0046] Moreover, in Figure 2 the circuit board 300, 500 of the luminaire 11 to which the
antenna foil 100 is connected to is the control electronics board 500 that is arranged
separately from the light source board 300 inside the luminaire 11. However, it is
also conceivable in an alternative setup that the light source board 300 of the luminaire
11 also comprises control electronics components 510 for controlling an antenna, the
control electronics components 510 also comprising the complementary connector 520
to which the antenna foil 100 is coupled via its connector 123. In this scenario the
control electronics components 510 are positioned on a side of the light source board
300 that is opposite to the side on which the light sources 310 are mounted.
[0047] As shown in Figure 2, the cover 600 may also comprise light emission influencing
elements 610 that interact with light outgoing from assembly of the light emitting
element 310 and optical element 200 (or incoming light coming from outside O towards
the assembly of optical element 200 and light receiving element 320). Via this cover
the respective light can be adjusted with regard to a specific installation situation.
It is further conceivable that the light modification characteristics of the light
optical element 200, the antenna foil 100 and/or the light emission influencing elements
610 are geared to each other.
[0048] Figures 3 and 4 show the same exemplary embodiment of an antenna foil 100, whereas
Figure 3 shows a schematic top view, and Figure 4 shows a schematic cross section
through the axis A illustrated in Figure 3. Each illustration shows a translucent
antenna foil 100 comprising an antenna, wherein the antenna foil 100 is mountable
on or in the respective optical element 200 of the device 10. The antenna foil 100
can be divided into two sections: an antenna portion 110 and a feeder line portion
120. In the antenna portion 110 an antenna conductor 111 of the antenna for emitting
and receiving signals is positioned, and the feeder line portion 120 includes a connector
123 having respective contacts 124 for coupling the antenna (i.e., the antenna foil
100) to a complementary connector 520 on a circuit board 300, 500 of the device 10.
The connecting portion 122 hereby connects the antenna conductor 111 and the connector
123 of the antenna foil 100. Both the antenna portion 110 and the feeder line portion
120 are substantially translucent.
[0049] The combined view of the Figures 3 and 4 shows that the displayed antenna foil 100
comprises three layers L1, L2 and L3, with an electrically conductive middle layer
L2 and two laminated foil layers L1, L3 sandwiching the middle layer L2. Hereby the
electrically conductive middle layer L2 comprises the antenna conductor 111. In the
displayed exemplary embodiment both the antenna portion 110 and the feeder line portion
120 are substantially equally constructed, such that in each section the conductive
middle layer L2 is arranged between the two foil layers L1, L3. Furthermore, a non-conductive
filler material 112, for example an insulator, is provided in the middle layer L2
between adjacent segments of the antenna conductor 111, such that optimal signal transmission
and receival is achieved. This non-conductive filler material 112 is also present
in edge regions of the middle layer L2 of the antenna foil 100, such that the edge
regions of the antenna foil 100 (besides the edge region with the contacts 124 of
the connector 123 being present) are formed by the laminated foil layers L1, L3 and
the conductive filler material 112 in-between. With this setup the antenna foil 100
is built utmost resistant and durable with regard to dust, moisture and water.
[0050] Further illustrated in Figure 4 the antenna conductor 111 may be present in different
height regions of the conductive middle layer L2, to achieve a preferred flexibility
with regard to a respective mesh formed by the antenna conductor 111. Hereby the non-conductive
filler material 112 may cover the antenna conductor 111 throughout the whole middle
layer L2. Alternatively to what is shown in Figure 4 it is also conceivable that the
non-conductive filler material 112 is (at least partly) integrally formed by the material
of the two sandwiching foil layers L1, L3. However, if a different material is preferred,
e.g., to achieve a certain flexibility or light transmission characteristic of the
antenna foil 100, different materials (as indicated in Figure 4) are ideally used.
[0051] It is also conceivable that the boundaries of the different layers L1, L2, L3 are
not as strict as schematically illustrated in Figure 4, such that, e.g., the thickness
of the foil layers L1, L3 may differ section wise, and hereby may be adapted to the
respective thickness of the middle layer L2, or to the respective thickness of the
antenna conductor 111 in the respective sections of the middle layer L2.
[0052] Also shown in Figure 4 on the right hand side is that in one end region of the feeder
line portion 120 only one of the two laminated foil layers L1, L3 is present (in the
displayed example, only the bottom layer L3 is present), and thus in this end region
the conductive middle layer L2 is uncovered forming the contacts 124 of the connector
123 of the feeder line portion 120. With this realization the connector of the antenna
foil 100 is formed utmost easy and at low cost, yet enabling good signal transmission
due to the uncovered antenna segments of the conductive middle layer L2. In the section
of the uncovered middle layer L2 a reinforcing layer 126 is provided on top of the
only foil layer L3 that reinforces stability of the feeder line portion 120 in the
area of the connector 123. This further increases durability of the antenna foil 100
and further eases connecting the antenna foil 100 to the respective complementary
connector 520 of the control electronics components 510 on the respective circuit
board 300, 500. Also shown in Figure 4 is the configuration of the contacts 124 being
provided with a metal print 125 that further enhances signal transmission due to better
electrical properties or better corrosion characteristics depending on the respective
material used. Hereby it is possible that in the section of the uncovered middle layer
L2 the uncovered segments of the antenna conductor 111 are provided with a silver
print and/or a gold print and/or a copper print, and/or a plasma metallization.
[0053] The complementary connector 520 is preferably a zero insertion force, ZIF, connector,
whereas this implementation further facilitates assembly of the device 10, and further
minimizes possible damages to the antenna foil 100.
[0054] Due to its high cost/usage efficiency the antenna conductor 111 preferably is made
out of silver. However, copper or gold are also conceivable to be used as a material
of the antenna conductor 111. With this configuration, an easy shaping of the antenna
is also possible, and the respective antenna shape can be adapted to individual needs
during production. Hereby the antenna conductor 111 forms a wire mesh, which is formed,
e.g., in a flat coil shape (as indicated in Figure 3). The form of the wire mesh hereby
is adapted for transmitting and/or receiving respectively desired signals, such as
NFC signals or other RFID signals, Sub-GHz frequency band signals, 2.4 GHz frequency
band signals, 5 GHz frequency band signals, other frequency bands signals, Zig-Bee
signals, and/or 5G signals, or the like.
[0055] The shown antenna foil 100 is further made flexible and reversibly bendable, such
that a repetitive adaption to the form of a respective optical element 200 is possible
without risking failure of the antenna.
[0056] In the shown embodiment the antenna foil 100 is substantially transparent, whereas
it is also conceivable that the antenna foil 100 - or at least the antenna portion
110 - has a light diffusing characteristic. If the antenna foil 100 is desired to
be transparent a degree of transparency of at least 90% is preferred.
[0057] If the antenna foil 100 itself (or parts thereof) shall have a light-diffusing effect
(e.g., by being opaque) this can be achieved e.g., by respective formed foil layers
L1, L3. Alternatively or additionally such a light diffusing effect of the antenna
foil 100 can be further achieved by a respective configuration of the middle layer
L2, and in particular of the antenna conductor 111. Hereby segments of the antenna
conductor 111 can be arranged such that the respective segments act as a light diffusor
of trespassing light, such that the antenna foil 100 has a light diffusing effect.
As previously described this can be combined in synergy with a respective configuration
of the optical element 200.
[0058] If the antenna foil 100 is not inserted inside the optical element 200 and hold therein
by respective fastening means, holding elements and/or guide elements that may be
integrally formed by the optical element 200 itself, it is preferred that the antenna
foil 100 has, at least in the antenna portion 110, an adhesive layer which is arranged
on one of the foil layers L1, L3, wherein this adhesive layer may be integrally formed
by the respective foil layer L1, L3. Via this adhesive layer coupling to the optical
element 200 is easily performed, facilitating setup of the device 10.
[0059] It is also possible, that at least one of the laminated foil layers L1, L3 in the
feeder line portion 120 differs from the respective laminated foil layers L1, L3 of
the antenna portion 110, to the extent that the feeder line portion 120 is more stiff.
With this implementation the durability of the feeder line portion 120 is increased,
which might be necessary due to the slim and narrow setup of this section.
[0060] Alternatively to the embodiment shown in Figure 2 the device 10 may also be a sensor
12, whereas the sensor 12 has a sensor board 300 with at least one sensor element
320. The optical element 200 hereby forms a light entry surface of the sensor 12,
and transmits light towards the sensor element 320. The such configured sensor allows
for communication via the monitoring foil 100 and further does not negatively influence
the crucial light guidance of the optical element 200. Preferably, the sensor 12 is
a passive infrared, PIR, motion detector, an infrared, IR, sensor, and/or a light
sensor.
[0061] Furthermore, it is possible that a device 10 comprises a sensor element 320 and a
light source element 310 in combination, whereas it is further possible that the optical
element 200 is shared between the two elements 310, 320.
[0062] Thus, devices with little space are possibly with an antenna foil 100 according to
the invention, as the foil requires almost no space being aligned flush on or in the
respective optical element 200 of the device 10. With its respective individual light
characteristics (translucent, transparent, diffusing, or the like) the antenna foil
100 further adapts ideally to the respective requirements of the device 10.
[0063] Furthermore, another implementation of a luminaire 11 is conceivable (not shown)
where the optical element 200 is a light guide plate for emitting light in a direction
perpendicular to the light insertion direction, whereas light insertion into the light
guide plate is realized by light emitting elements 310 being laterally arranged on
front faces of the plate-shaped light guide. Hereby the antenna foil 100 is arranged
on a surface of the light guide plate opposite to the light emission surface of the
light guide plate. Via this implementation, wireless communication of the luminaire
11 is improved by usage of the antenna foil 100, while the antenna foil 100 is firstly
not noticeable for a user and also does not influence light emission of the luminaire
11 at all, or at least not in a negative manner.
[0064] Also not shown in the figures but nevertheless conceivable is an implementation of
the antenna foil 100 and the optical element 200, where the antenna foil 100 is (preferably
reversibly) insertable inside the optical element 200, whereas due to its foil characteristics
the antenna foil 100 adapts to the respective shape of the optical element 200. Hereby
the optical element 200 may comprise respective rail elements on the inside which
guide and preferably also hold the antenna foil 100 in place. This allows for situational
adaption of the antenna foil 100 with regard to the respectively needed signal transmission
type.
[0065] The communication line realized via the antenna foil 100 may be used for integration
of the respective device 10 inside an existing system, for initial setup of the device
10, maintenance, and/or other checkups.
[0066] With the antenna foil 100 according to any of the herein described embodiments, respectively
the kit assembly of the antenna foil 100 and the optical element 200, respectively
the device 10 comprising the kit, an utmost easy and interference-free communication
between a mobile device used by a user and the respective device 10 is achieved.
1. A translucent antenna foil (100) comprising an antenna, for use in a device (10) having
an optical element (200),
wherein the antenna foil (100) is mountable on or in the optical element (200) of
the device (10),
wherein the antenna foil (100) has an antenna portion (110) and a feeder line portion
(120),
wherein in the antenna portion (110) an antenna conductor (111) of the antenna for
emitting and receiving signals is positioned, and
wherein the feeder line portion (120) includes a connector (123) having respective
contacts (124) for coupling the antenna to a complementary connector (520) on a circuit
board (300, 500) of the device (10), and a connecting portion (122) connecting the
antenna conductor (111) and the connector (123),
wherein both the antenna portion (110) and the feeder line portion (120) are substantially
translucent.
2. Antenna foil according to claim 1,
wherein the antenna foil (100) comprises an electrically conductive middle layer (L2)
and two laminated foil layers (L1, L3) sandwiching the middle layer (L2);
wherein the electrically conductive middle layer (L2) comprises the antenna conductor
(111);
wherein preferably both the antenna portion (110) and the feeder line portion (120)
are equally constructed with;
wherein preferably a non-conductive filler material (112), for example an insulator,
is provided in the middle layer (L2) between adjacent segments of the antenna conductor
(111) and further preferred in edge regions of the antenna foil (100).
3. Antenna foil according to claim 2,
wherein in an end region of the feeder line portion (120) only one of the two laminated
foil layers (L1, L3) is present, and thus in this end region the conductive middle
layer (L2) is uncovered forming the contacts (124) of the connector (123) of the feeder
line portion (120);
wherein preferably in the section of the uncovered middle layer (L2) a reinforcing
layer (126) is provided on top of the only foil layer (L1, L3);
wherein preferably in the section of the uncovered middle layer (L2) the uncovered
segments of the antenna conductor (111) are provided with a metal print (125), preferably
with a silver print and/or a gold print, forming the contacts (124) of the connector
(123) of the feeder line portion (120).
4. Antenna foil according to any of the preceding claims,
wherein the antenna conductor (111) comprises copper and/or silver and/or gold; and/or
wherein the antenna foil (100) is made flexible and reversibly bendable.
5. Antenna foil according to any of the preceding claims,
wherein the antenna foil (100) is substantially transparent and preferably has a degree
of transparency of at least 90%; and/or
wherein the antenna foil (100) itself has a light-diffusing effect, and preferably
is opaque,
wherein further preferably the antenna conductor (111) is such arranged within the
middle layer (L2) that it contributes to the diffusion effect.
6. Antenna foil according to any of the preceding claims,
wherein the antenna foil (100) has, at least in the antenna portion (110), an adhesive
layer which is arranged on one of the foil layers (L1, L3);
wherein preferably the adhesive layer is integrally formed by one of the foil layers
(L1, L3).
7. Antenna foil according to any of the preceding claims,
wherein the antenna conductor (111) forms a wire mesh, which is formed, e.g., in a
flat coil shape;
wherein further preferably the wire mesh is designed for transmitting and/or receiving
NFC signals, other RFID signals, Sub-GHz signals, 2.4 GHz frequency band signals,
5 GHz frequency band signals, Zig-Bee signals, and/or 5G signals or other frequency
signals.
8. A device (10) comprising an optical element (200), a circuit board (300, 500) and
a housing (600, 700), wherein the optical element (200) and the circuit board (300,
500) are arranged on an inside (I) of the device (10), and the device (10) further
comprises a light emitting element (310), such as a LED (310), or a light receiving
element (320), such as a sensor element (320),
wherein the device (10) further comprises an antenna foil (100) according to any of
the preceding claims 1 to 7;
wherein the optical element (200) is made of plastic and/or glass;
wherein the antenna foil (100) is mounted on and/or in the optical element (200);
and
wherein the antenna foil (100) is coupled via its connector (123) to the circuit board
(300, 500).
9. Device according to claim 8,
wherein the optical element (200) together with the light emitting or light receiving
element (310, 320) forms an effective optical field (EOF) of the device (10),
wherein at the antenna portion (110) of the antenna foil (100) is arranged in the
device (10) such that only components of the device (10) made of plastic and/or glass
are arranged within the effective optical field (EOF) between an outside (O) of the
device (10) and the antenna portion (110).
10. Device according to claim 8 or 9,
wherein the antenna portion (110) of the antenna foil (100) is arranged on a side
of the optical element (200) facing the light emitting or light receiving element
(310, 320); or
wherein the antenna portion (110) of the antenna foil (100) is disposed inside the
optical element (200) itself.
11. Device according to any of the preceding claims 8 to 10,
wherein the antenna foil (100) is coupled to the optical element (200) by means of
an adhesive element, for example by means of an adhesive layer arranged on an outer
surface layer of one laminated foil layer (L1, L3) of the antenna foil (100);
or wherein the antenna foil (100) is coupled to the optical element (200) by means
of holding elements and/or guide elements, which are preferably formed by the optical
element (200) itself.
12. Device according to any of the preceding claims 8 to 11,
wherein the circuit board (300, 500) of the device (10) comprises control electronics
components (510) for controlling an antenna, the control electronics components (510)
also comprising the complementary connector (520) to which the antenna foil (100)
is coupled via its connector (123);
wherein preferably the circuit board (300, 500) of the device (10) is a control electronics
board (500) for controlling an antenna;
wherein preferably the complementary connector (520) is a zero insertion force, ZIF,
connector.
13. Device according to any of the preceding claims 8 to 12,
wherein the device (10) is a luminaire (11);
and the luminaire (11) has a light source board (300) having a plurality of light
sources (310), e.g., LEDs (310), and wherein the optical element (200) transmits light
being emitted from the light sources (310);
wherein preferably the light guide is a diffuser arranged subsequent to the light
source board (300) in the light emitting direction of the light sources (310).
14. Device according to claim 13 in combination with claim 12,
wherein the circuit board (300, 500) of the luminaire (11) is the control electronics
board (500) that is arranged separately from the light source board (300) inside the
luminaire (11); or
wherein the light source board (300) of the luminaire (11) also comprises control
electronics components (510) for controlling an antenna, the control electronics components
(510) also comprising the complementary connector (520) to which the antenna foil
(100) is coupled via its connector (123), whereas the control electronics components
(510) are positioned on a side of the light source board (300) that is opposite to
the side on which the light sources (310) are mounted.
15. Device according to any of the preceding claims 8 to 12,
wherein the device (10) is a sensor (12),
and the sensor (12) has a sensor board (300) having at least one sensor element (320),
wherein the optical element (200) forms a light entry surface of the sensor (12),
and transmits light towards the sensor element (320);
whereas preferably the sensor (12) is a passive infrared, PIR, motion detector, an
infrared, IR, sensor, and/or a light sensor.