NL8303444A - PHASE ROTATOR CONTROL FOR A PHASED-ARRAY ANTENNA. - Google Patents

Description

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Phase shifter control for a phased array antenna

The invention relates to a phase-turner control for a 'phased-array' antenna, wherein the antenna modules comprising the phase turners are arranged in rows and columns, the phase turner control being provided with calculating means for calculating from at least the determine the beam direction, the frequency of the energy to be emitted and the position of each individual phase shifter in the array * determine the phase-10 setting desired for the individual phase shakers.

Such a phase shifter control is known from e.g. M.I. Skolnik, Introduction to radar systems, 2nd ed.,. McGraw-Hill Kogakusha, Ltd., 1980, biz. 323- Phase rotation for the respective antenna modules is determined there in a beam-steering computer. If these phase rotations are to be determined per radar pulse to be transmitted, the usual large number of antenna modules will require an exceptionally large computer capacity. This capacity can be limited by refraining from a possible phase setting per pulse and by making this setting possible only after transmission of a certain pulse series or by allowing the phase setting to proceed according to certain patterns. The object of the invention is now to provide such a phase shifter control, whereby a (phase setting per pulse and per antenna module) remains possible with a greatly reduced computer capacity.

According to the invention, the calculating means are formed for this purpose by a central calculator, which determines from the beam direction to be determined and the frequency of the energy to be transmitted which determines terms in the mathematical expression for the desired phase setting, which are the same for all phase shifters, and a Calculation chip present in each antenna module to determine the desired phase setting from the terms determined by the central computer and the position of the individual phase shifters in the array *. The total λ T r. * Λ!% L · O J V i "" - 2 - calculation operations to be performed are therefore split into operations to be performed centrally on the one hand and operations to be performed locally, i.e. at antenna module level, on the other.

5 If, when introducing a Cartesian coordinate system, the x and y axes determine the antenna plane and the z axis follows the main antenna axis, and it is further assumed that the beam direction makes an angle met with the z axis, while projecting the beam direction on the xy plane 10 an angle φ with the x-axis is supposed to be made, then for the phase differences and ψ between phase shifters adjacent in the x and y directions: (ψχ = - ^ d- | .cos <p. sin £, \ φ7 »^ d2.sin φ.sin-0, 15 where d- | represents the distance between two antenna modules in the x direction and the distance between two antenna modules in the y direction. right above and next to each other, then for the phase rotation for the antenna module m, n: 20 Ψ m, n ah +

On the other hand, the rows of antenna modules are alternately spaced ^ d- | shifted in the x direction relative to each other, this phase rotation, while maintaining the row and column configuration in the array, becomes: 25 ^ ιη, η "+ + n * ^ y

For the sake of simplicity, the first situation will be assumed in the following, so that

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r m, n a m * "X dl-oos cp.siné? + n .— ^ ~ d2.sin cp.sin #.

If a space-fed phased-50 array antenna is used, either a lens array or a reflect array, a correction for the expression for n should be included. This correction takes into account the transition from a spherical to a flat phase front. To this end, the term for! / M> n includes a term Cm> n.

55 For the transition from a purely spherical to a flat phase front Γ2 2 21 holds: Cm = \ / p + x + y - p, where p is the distance from the radiant center of the Hoom spotlight or other radiation radiation used 83 0.5 44 4 - 3 - element up to the antenna plane. In practice, such a purely spherical phase front is not present.

In addition, since the values Cmjn also appear to be frequency-dependent and a mathematical relationship between the value Cm> n and the frequency cannot be indicated, one has to assume empirically obtained σπι, η ~ values for different frequency intervals.

It may sometimes be desirable to be able to widen the beam when making a search movement with the antenna beam at certain elevations. For this purpose, an additional phase rotation m m> n must be introduced per antenna module, so that not a flat but, for example, a square phase front is formed.

The following relationship applies to the phase shift: ^ m, n K ^ d-i.cos φ.sinO + dg.sin q> .sinS + B. £ m, n, where B * 0 is used as no beam broadening; if it is, then B * 1. K is a constant. It is known to calculate this phase rotation for each antenna module separately in a beam-steering computer. In accordance with the invention, however, the calculation is split into a number of operations to be performed centrally and a number of operations to be performed locally in each antenna module. The results of the centrally performed operations can then be fed to all antenna modules simultaneously.

Centrally the terms a «- ^ d-j.cos qi.sin6,

K K

b = - ^ d2.sin φ. sin © and c. = —Are calculated. In the calculation chip of each antenna module, the values 30 d = m, e> n, f * Cm> 11 and g * £ m, n can be entered once, so that in each calculation chip only the calculation ^ m, n * ad + ' be + cf + Bg must be executed.

The values d, e, f and g can be burned into any calculation chip; however, they may also be operated by the central u - each time the array is brought into its operative state. · - ^ - 4 - calculator are supplied. The B value can then also be supplied; however, this value can also be entered separately or simultaneously with the values a, b and c when the array antenna is in the operating state.

The division between operations to be carried out centrally and locally can also be carried out differently than mentioned above. For example, one can centrally determine the values • jaa cos qj.sinö, b · sin cp.sinÖ and c »and, after the values d = Kmd ^, e» Knd2, f »£ * cm, n and ® = ^ m, n 10 have been brought into the respective calculation chips, locally the phase shift </ tm n = c. £ ad + be + fj + Bg, or centrally 111 the values a * -y cos φ. sin #, b = «sin qp.sinO and c - -y and, after the values d * Kmd ^, e« Knd2, f »K.Gm ^ a and g» £ m, n 4n <* e lay chips locally, the phase 15 'rotation »ad + be + cf + Bg.

The invention will now be further elucidated with reference to the accompanying figure, which shows an example of a phase-shift control according to the invention in block diagram.

20 In this figure, 1 represents the central calculator. The calculation chip belonging to each antenna module is indicated by 2 and the associated phase shifter with 5 · The antenna modules are therefore formed by the elements "n, 2 and 3 together. The data transports from the central calculator 1 to the individual antenna modules 2,3 are via the buffer elements 4 and with the aid of the addressing circuit 5

Before the array antenna is brought into the operational state, the values d = m, e * n, f * 30 and g * ia <* e are first read as separate calculation chips. The d values are the same for the columnar antenna modules. The buffer elements 4 are therefore filled with a certain m value from the central computer. The e values are the same for the arrayed antenna modules 35. Before entering these values, the buffer elements 4 are all filled with the same n value from the central calculator, namely m successively with a V V - - y -. · • Λ i - 5 - * .-: new n value. The f and g values are different for each antenna module. The buffer elements are filled successively from the central calculator with a certain C or £ value r m, n mtn 5 for the input of these values m. In all cases, the addressing circuit 5 causes this information to be included in the respective antenna modules.

Since the C values are frequency-dependent m, n, a number of such values are preferably introduced into each antenna module, so that, if the array antenna is in the active state, a correct C value for the local each time the frequency changes m, n calculations to be performed are available.

If the array antenna is in the active state, then the antenna modules can be fed each time

K K K

values a »* ^ d ^ .cos q> .sin £, b = - ^ dg. sintp.sinöen c the same for all antenna modules. The buffer elements 4 are successively filled from the central computer 1 with the same a, b or c value, while again using the addressing circuit 5 is caused to include this information in the respective antenna modules. While transmitting a radar pulse and listening to an echo, the a, b and c values for a subsequent radar pulse to be transmitted are introduced into the antenna modules. In the dead time before the next radar pulse is transmitted, only a command signal is sent simultaneously to all antenna modules, in the same way as the a, b and c values, at which the array switches to the newly selected beam direction.

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Claims (4)

1. Phase-turner control for a phased-array * antenna, wherein the antenna modules comprising the phase turners are arranged in rows and columns, the phase turner control being provided with calculating means for determining the frequency of the frequency of the beam direction from at least the beam direction to be determined. energy to be emitted and the position of each individual phase turner in the array to determine the phase setting desired for the individual phase turners, characterized in that the calculating means are formed by a central calculator, which is determined from the beam direction to be determined and the frequency of the energy to be emitted which determines terms in the mathematical expression for the desired phase setting, which are the same for all phase shifters, and a calculation chip present in every 15 antenna module to convert from the terms determined by the central calculator and the position of the individual phase shifters in determine the desired phase setting in the array. Phase-shifter control according to claim 1, wherein a space-fed phased-array antenna is used, v, characterized in that in each computing chip, for the phase adjustment of each individual phase-shifter and the transition from a spherical the frequency-dependent correction values required for a flat phase front can be brought. Phase-shift control according to claim 1 or 2, characterized in that a correction value required for the phase adjustment of each individual phase-shifter and the beam-width adjustment can be introduced into each calculation chip. 'J * J o q 4 J