The present invention relates to a lens for steering the exit direction of an electromagnetic wave which is incident upon the lens, said lens comprising a main body of a ferroelectric material with at least a first main surface and a first transformer which is adjacent to said first main surface of said ferroelectric body. The lens additionally comprises means for creating a first DC-field in a first direction in the main body, and the incident electromagnetic wave will enter and exit the lens through the transformer.
Ferroelectric materials have a dielectric constant which can be altered if a DC-field is induced in the material. This property has been used to manufacture lenses of ferroelectric materials for electrical steering of electromagnetic beams, such as an antenna beam, the beam being the “output” from the lens of an electromagnetic field which has been incident upon the lens.
A lens which is made from a ferroelectric materials and which is used for electrically steering the exit direction of a beam which is incident upon the lens and exits the lens is known from IEEE Transactions on Antennas and Propagation, pp 458-468, volume 47, no 3 1999, “Voltage-Controlled Ferroelectric Lens Phased Arrays”.
A drawback of the device discussed in this article is the complexity of the design and the price. The device uses a multitude of traditional waveguides filled with ferroelectric materials and input/output matching sections which would increase the cost of the device.
Another ferroelectric beam-steering lens is known from 33rd EuMC WS6 proceedings, pp 79-82. Drawbacks of the device disclosed in this paper seem to be a very high charging time constant, as well as quite a high voltage (in the order of magnitude of 20 kV) needed to drive the lens. Additionally, the fabrication of a large area ferroelectric plates (lens) as disclosed in this paper is complicated—it is hard to fabricate the large size (>5×5 cm2) plates of the design with acceptable densification and uniformity.
There is thus a need for a ferroelectric lens for steering the output direction of an incident electromagnetic beam which is less expensive and less complex to manufacture than those known at present. In addition, such a new lens should also need lower driving voltages than lenses which are known at present.
These needs are addressed by the present invention in that it discloses a lens for steering the exit direction of an electromagnetic wave which is incident upon the lens, the lens comprising a main body of a ferroelectric material with at least a first main surface, also comprising a first transformer which is adjacent to said first main surface of said ferroelectric body.
The electromagnetic wave will enter and exit the lens through the transformer, with the lens additionally comprising means for creating a first DC-field in a first direction in the main body.
According to the invention, the lens's main body of ferroelectric material comprises a plurality of discrete slabs of the ferroelectric material, each slab in said plurality also comprising a first and a second electrode of an electrically conducting material. Also, the means for creating a DC-field can create a gradient DC-field in said first direction, using the first and second electrodes in the plurality of slabs, by means of which the dielectric constant in the main body will also be a gradient in said first direction, thus enabling steering of the exiting electromagnetic wave, and offer design flexibility with low expenses.
Thus, by means of the invention, a beam-steering lens made from a ferroelectric material is obtained which will be less expensive to produce than previously known such lenses, and, as will become apparent from the more detailed description, will also require much lower control voltages than previously known such lenses.
Suitably, the means for creating a DC-field are adapted to create said first DC-field in a first direction which is essentially parallel to said first main surface of the main body.
In a preferred embodiment of the invention, the lens additionally comprises a second transformer, and the main body of ferroelectric material has a second main surface, with each of the first and second transformers being arranged adjacent to one of the main surfaces of the main body, so that the electromagnetic wave will enter the lens through one of the transformers and exit through the other of the transformers.
The invention will be described in more detail with reference to the appended drawings, in which
a and 8b show a variation of the component of
a and 9b show versions of the invention, and
a and 11b show alternative embodiments of the lens of the invention, and
As illustrated schematically in
An application of the ability to change the dielectric constant of the body of ferroelectric material is shown in
According to the invention, the DC-means 140 are used to create a DC-field in a first direction in the body 110, the direction shown in
A result of the gradient DC-field is also shown in
The fact that the exit direction of an incident wave can be changed by means of imposing a gradient DC-field upon the ferroelectric body means that a lens according to the invention can be used as a beam steering device. The device 100 shown in
In addition, which was not shown in
Thus, there should suitably also be a transformer where a wave will exit the lens. This can be accomplished by letting the transformer 220 surround the lens at both the intended entry and exit surfaces for the wave, i.e. by letting the first transformer be in one solid contiguous piece, or, as shown in
As shown in
Also, according to the invention, as shown in
Thus, a plane electromagnetic wave 240 which is incident upon the lens 200 in a direction normal to the first main surface 207 of the body of ferroelectric material 210 will enter the lens through the first transformer 220 and the first main surface 207 and exit the body 210 through the second main surface 208 and the second transformer 222.
As illustrated in
Accordingly, the lens of the invention comprises means (DC+, GND) for introducing a first DC-field in a first direction in the main body. This will now be described in more detail with reference to
The matrix is of course only one suitable form for the ferroelectric body 210, as is the elongated box-like shape of the individual slabs, many other forms of slabs and ferroelectric bodies can be realized within the scope of the invention. For example, in this particular embodiment, each row, i.e. elements 21011-2101N etc. can be one contiguous slab, so that the body 210 instead comprises a plurality of “boards” arranged on top of each other.
As mentioned previously, the lens of the invention also comprises means for creating a DC-field gradient in the lens. These means can be seen more clearly in
As can be seen, the ground lines 370 are connected to a common ground point GND, and the DC-lines are connected to a DC-power supply “V”. Before the means for creating the DC-field are described further, the individual elements, the “slabs” of the ferroelectric body 210 will now be described in more detail, with the aid of
According to the invention, the slabs in the matrix, as shown in
Returning now to
Let's consider the slabs in the “rightmost” column, i.e. slabs 2101N, 2102N . . . 210NN. Slab 2101N is arranged so that its bottom electrode is in contact with the top electrode of the slab immediately below it, i.e. slab 2102N. This is the principle adhered to with all of the slabs (except, for natural reasons, the uppermost and lowermost of the slabs) in any specific column: the bottom electrode of each slab is in contact with the top electrode of the slab immediately below it.
A number of connection points are thus created at the intersection between two slabs, where each connection point comprises the bottom electrode of one slab and the top electrode of the next slab immediately below. If the two electrodes do not extend to the sides of the slabs so that the connection points can not be accessed at the sides, an extra conductor can be introduced to facilitate electrical access to the meeting points of the two electrodes.
Thus, at the intersections or connection points between two slabs, it will be possible to establish a potential by connecting the connecting point to a DC-feed. This is what is done in the embodiment of
Using VDC=7V, there will then be a voltage of 1 V across each resistor, with the voltage between any one resistor and ground being shown next to the resistors, said voltage to ground varying as a gradient from 0 to 7 volts.
With the exception of the first slab, i.e. slab 2101N, the electrode on one side (top/bottom) of each slab will be connected to a point in the ground line 370, and the electrode on the other side (bottom/top) of the same slab will be connected to a point in the second potential line 380.
Thus, one of the electrodes in each slab will be connected to ground, and the other electrode will be connected to the potential line supplied by the DC-feed.
In order to create the desired DC-gradient over the slabs, starting from the slab which will be the lowest potential in the DC-gradient, and going in the direction of the desired gradient, each slab is connected to a point in the second potential line 380 which has a higher potential than the point in the next slab which is connected to the second potential-line 380.
In order to facilitate the understanding of this,
In order to further facilitate the understanding of this principle, the table below shows, for the slabs in the rightmost column, column N, the potential between the point in the slab which is connected to the DC-line and ground. Since there are 16 rows shown in the drawing, which is of course merely an example, the slab at the bottom right hand corner will here be denoted 21016,N.
Thus, there is a DC-gradient created over the body 210 of ferroelectric material, the gradient being indicated by the arrow G in
Since it is possible to control the gradient by means of controlling the potential line 380, it will now be realized that this control can also be used to control the output direction Ω of the exiting electromagnetic wave 250 which was shown and described in connection with
Another important principle of the invention will also have emerged from the description of the DC-means or biasing means: the DC-field which is created in a lens of the invention will be essentially parallel to the E-field of the incident electromagnetic wave shown in
As with the previous embodiments, the embodiment 500 is based on a body of ferroelectric material 510. The lens 500 comprises one or several matching transformers at the main surfaces of the body, which is in similarity to the embodiment shown and explained in conjunction with
The ferroelectric body 510 is also comprised of a plurality of slabs, 51011-510NN, which in the drawing are shown as rectangular box-like structures arranged as a matrix with N rows and N columns. One of the slabs used in the embodiment 500 is shown in more detail in
As with the slabs of the previous embodiment, the slab 510XX shown in
However, as opposed to the previously shown slabs, the slab or TEM-waveguide 510XX of the embodiment 500 has a two-layered structure, shown in
A first layer 605 of ferroelectric material is arranged on top of a second layer 606 of a ferroelectric material, suitably but not necessarily the same kind of ferroelectric material. Between these two layers 605, 606, there is arranged a layer of conducting material, which is suitably a material with a high resistivity, for reasons which will become clear later on in this description. As with the slabs shown earlier, the slab 510XX can be seen as an elementary TEM-waveguide, and comprises a first and a second electrode of a conducting material with low resistivity, the first electrode 603 in this example being arranged on a “top” surface of the slab, and the second electrode 604 being arranged on the opposing bottom surface of the slab.
Thus, as shown in
As show in
As shown in
As can be seen in
The next after that of the third electrodes is then connected to the second side of the second voltage divider. In short, the principle which will now have been realized is that one voltage divider from each of the DC-supplies, V1, V2, will connect two adjacent third electrodes.
The connection points which are created at the intersections between the slabs of the body 510 are also utilized in this embodiment, in this case by being connected to a grounding network or ground lines 570.
Using the principle described in connection to
Thus, by means of controlling the two voltage supplies V1 and V2, the dielectrical constant ∈ of the board can be made to vary as a gradient in both the x- and the y-directions, by means of which the exit direction of the incident electromagnetic wave can be controlled in both directions, which was the desired result of the embodiment 500.
It should be mentioned here that in the ferroelectric body 510, in similarity to the ferroelectric body 210, the elements of one column, e.g. elements 51011-5101N, can be one contiguous slab instead of discrete elements, i.e. the body 510 can consist of “boards” stacked on top of each, and other.
The embodiments shown above and in the appended drawings are merely examples to facilitate the understanding of the invention, it will be realized that many variations are possible, both when it comes to the structure of the TEM-waveguides (“slabs”) and when it comes to the means for creating the DC-gradient field.
One example of an alternative embodiment 700 is shown in
However, as an alternative, the lens 700 has a concave first main surface 707 and a plane second main surface 708, with the respective matching transformers 720, 722, having corresponding shapes. This shape of the components of the lens make it possible to, for example, shape the beam form and/or beam width of the output beam.
Some examples of materials and dimensions for a lens according to the invention will also be given. It should be pointed out that although these materials and examples are suitable for a lens according to the invention, these are examples only, and should not be seen as restricting the scope of the invention.
As an example of a suitable material for the ferroelectric slabs of the ferroelectric body, mention can be made of BaxSr1-xTiO3, where 0≦x≦1.
When it comes to choosing materials for the matching transformers, any material with a suitable dielectric constant may be chosen, i.e. the following formula should be adhered to:
∈transformer=√{square root over (∈ferr.lens)} (1)
Regarding the dimensions, in other words w, h, l, of the “slabs” or TEM-waveguides in the body of ferroelectric material, the following can be said: the width w may be determined, for example, by ease of fabrication. In other words, the smaller the width w of the waveguides is, the higher the yield will be, if the waveguides are produced as parts of a larger block.
As for the height h, or that dimension which will be the height when the waveguides are arranged in the lens as shown above, the height h should be less than the half of the intended operating wavelength of the lens. Hence, we can talk about a specific height only in connection with a specific frequency. If, for example, the lens is to be designed to work at 10 GHz using ferroelectric with ∈=200 m we then have:
Thus, the general formula for the height h of the slabs is:
where c is the speed of light, f is the intended operating frequency (centre frequency) of the lens, and ∈ferr is the dielectric constant of the ferroelectric material used.
An example of a suitable height h of a slab is in the are of 0.5-1 mm. This is merely an example of a suitable value, and is in no way restrictive for the invention.
With suitable ferroelectric materials, a typical value of the control voltage would be 10V/μm in the direction in which the voltage is applied. Thus, in the case of a slab with h=1 mm, the control voltage would be 1 kV.
The length l of the slabs is defined by, among other things, the required range of the scanning angle of the lens. A typical value for l would be in the range of approximately 10-20 mm.
Regarding the matching transformers, their depth, i.e. the dimension which is perpendicular to the main surfaces of the body of ferroelectric material, the depth of the transformers should be a quarter-wavelength of the intended operating frequency. For the frequency 10 GHz and dielectric constant of ferroelectric ∈=200, and using equation (1) above for the dielectric constant of the transformer, we would thus have a transformer depth dTRANS:
As an example of a suitable material for the high resistivity film, mention may be made of LaMnO3/SrTiO3.
b shows a variation 820 of the waveguides shown above: in
a and 9b show versions 910 and 920 of a lens according to the invention seen from the same perspective as in
Additionally, the surface of the transformers 911, 921, which is intended to face outwards from the lens 910, 920 is smooth, but in the case of
In the case of
In
a shows another embodiment 1100 of a lens according to the invention, seen in the same perspective as the lens in
The main difference between the embodiment 1100 and those shown previously is the following: the TEM-waveguides of the lens 1100 are equipped with a first and a second electrode, but not on those sides which will face the waveguides in the rows below and, where applicable, above. Instead, the waveguides of the lens 1100 have a first and a second electrode on those sides which face neighbouring waveguides in the same row.
This is illustrated using two adjacent waveguides 1102 and 1104 in the lens 1100. Thus, the waveguide 1102 has a first 1101 and a second 1103 electrode on each of said sides, and shares the second electrode 1103 with the waveguide 1106 which is immediately adjacent to it on that side.
As can be seen in
One benefit of the embodiment of
Naturally, an embodiment where each waveguide can b addressed individually will naturally allow for greater flexibility when it comes to shaping the gradient in the ferroelectric body.
b shows an alternative embodiment 1105 of the lens shown in
The embodiment shown in
In the example shown, the waveguides are rectangular and box-like, with a basic structure similar to that shown in
As an example, consider waveguide 120011: this waveguide has four electrodes, one on each of said sides. The waveguide 120011 has one electrode on one side in common with the neighbouring waveguide in the “y”-direction, using the same coordinate system as previously, i.e. waveguide 120012.
Additionally, waveguide 120011 also has one of its electrodes in common with the neighbouring waveguide 120021 in the “x”-direction. Since waveguide 120011 is arranged in the upper left hand corner of the matrix, and thus has no neighbours in two directions, two of the electrodes will not be shared with any of the other waveguides but the principle will have been realized.
With the embodiment shown in
As mentioned in conjunction with the embodiments shown in
Also, it should be pointed out that the embodiment shown in
Finally,
b shows one of the individual waveguides of
The invention is not limited to the examples of embodiments shown above, but may be varied freely within the scope of the appended claims. Thus, the waveguides may be given any number of cross sectional shapes, as is well known in waveguide technology. For example, cross sectional shapes which could be possible are round, oval, hexagonal, etc.
Also, the waveguides of the invention can be used within other applications. For example, the waveguides could be used as phase shifters in hybrid integrated circuits.
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/SE04/01822 | 12/8/2004 | WO | 00 | 6/8/2007 |