KR102375697B1 - Method and appartus for modulating baseband signal in beam space multi-input mult-output - Google Patents

Abstract

A method and apparatus for modulating a baseband signal in beam space MIMO are disclosed. The baseband signal modulator may calculate load values of the plurality of antenna elements by using the baseband signal. In addition, the baseband signal modulator may change the phase or magnitude of the baseband signal or the first band signal having a higher frequency than the baseband signal in response to the frequency of the baseband signal.

Description

Method and apparatus for modulating baseband signals in beam space MIMO

The present invention relates to a method and apparatus for modulating a baseband signal in beam space MIMO.

Recently, a multi-input multi-output (MIMO) technique has been adopted in various communication technologies. This MIMO technique has the advantage of increasing the data rate and maximizing the frequency efficiency. In addition to IEEE 802.16 and IEEE 802.20, which are portable Internet systems, the Wibro system and 3GPP cellular communication system adopt the MIMO technique.

Transmission performance in such a MIMO communication system generally increases in proportion to the number of antennas. Therefore, in order to maximize MIMO performance, the number of antennas needs to be increased, which leads to an increase in the number of RF chains. When the number of antennas increases, implementation complexity increases and the size of the system increases, so there is a disadvantage that the number of antennas cannot be significantly increased. In order to overcome this limitation, research for achieving MIMO performance using one RF or an enemy number of RF chains has been recently conducted. As a representative example, there is a beam space MIMO technology using an Electrical Steering Parasitic Array Radiation (ESPAR) antenna or a Load Modulation Antenna.

The beam space MIMO technology is different from the general MIMO technology in terms of antenna/RF and baseband.

First, the antenna/RF aspect will be described as follows. A typical MIMO technology configures an antenna using a plurality of active antenna elements, but the beam space MIMO technology configures an antenna using one or a small number of active antenna elements and a plurality of parasitic antenna elements. The advantage of such a beam space MIMO technology is that the number of antennas can be extended through the plurality of parasitic antenna elements and the distance between the plurality of parasitic antenna elements can be reduced. In addition, since the beam space MIO technology uses one or an enemy number of RF chains, the RF part is not complicated and can be implemented with a small size.

In terms of baseband, it is explained as follows. A typical MIMO technology uses a plurality of active antenna elements and radiates a modulated baseband signal for each active antenna. Accordingly, the phase and magnitude of the signal radiated through the active antenna is finally determined by the phase difference and magnitude difference due to the path through which each signal is transmitted. The signal passes through each path, and the phase and magnitude of each signal radiated from the antenna is determined by the phase noise of the local oscillator or RF damage such as IQ imbalance of the transmission path. ) will be affected by The system can be configured by measuring such RF damage and compensating for it in terms of baseband, or considering these specifications when configuring RF. However, since these RF damages (ie, IQ Imbalance or Phase Noise) do not change abruptly and have almost constant values, there is no problem even if they are compensated for with a long period.

In the beam space MIMO technology, a plurality of orthogonal beams are generated by decomposing the entire antenna beam pattern generated by one or a few active antennas and a plurality of parasitic antennas. The baseband signal is mapped to these plurality of orthogonal beams. Current values flowing through the plurality of parasitic antennas are changed by the baseband signal and the impedance values of the plurality of parasitic antennas, thereby finally generating a radiation signal mapped to a beam. And the phase and magnitude of the finally emitted signal are determined by this current value. That is, by changing the load value (impedance values of the plurality of parasitic antennas), the phase and magnitude of the finally emitted signal are changed, and a desired radiation signal is generated through this.

On the other hand, the plurality of parasitic antennas are implemented by a variable impedance element, and the value of the variable impedance element is affected by a signal generated in the parasitic band. That is, whenever the value of the signal generated in the baseband is changed, the load value must be changed. Therefore, tuning is required whenever the subband signal is changed, and the beam space MIMO technology needs to be tuned at a faster cycle than the general MIMO technology.

A current required for each antenna element (ie, a plurality of parasitic antennas) is calculated in a ratio form in response to a ratio of signals generated in the baseband, and an impedance value of each antenna element is determined using the current ratio. However, this conventional method does not pose a problem in a single carrier system, but the following problem occurs in a broadband system or a multi-carrier system. When the variable impedance is implemented as a capacitor component or an inductor component, since a reactance component of the variable impedance varies according to frequency, a problem may occur in a wideband system or a multi-carrier system.

In other words, in beam space MIMO, it is necessary to consider the change in the variable impedance value due to frequency. Signals may not be transmitted properly due to changes in the variable impedance value due to frequency. When the same symbol is transmitted at different frequencies, the phase difference and the magnitude difference are not uniformly radiated. Due to this, the phase and magnitude of the final emitted signal do not preserve the phase and magnitude of the baseband. When measuring the phase and size of a channel with a reference signal distributed along the frequency axis, a reliability problem may occur.

An object of the present invention is to provide a method and apparatus for compensating for a phase or magnitude of a baseband in beam space MIMO.

According to an embodiment of the present invention, a baseband modulation apparatus is provided. The baseband modulation device includes a plurality of antenna elements, an antenna array emitting a beam space Multi-Input Multi-Output (MIMO) signal, a baseband unit generating a baseband signal, and converting the baseband signal to the baseband signal. a band converter for converting a first band signal having a higher frequency than the frequency of the band signal, calculating the load values of the plurality of antenna elements using the baseband signal, and setting the calculated load values in the antenna array a load calculator, a signal change controller configured to set a change value for at least one of a phase and a magnitude of the baseband signal in response to the frequency of the baseband signal; and a signal changing unit for changing at least one of the first band signals.

The signal change controller may set the change value so that at least one of a phase change and a magnitude change of an antenna signal radiated through the antenna array for each frequency of each baseband signal is the same.

The signal change controller may set the change value so that the phase change of the antenna signal radiated through the antenna array is the same for each frequency of the baseband signal having the same phase.

The signal change controller may set the change value so that the amplitude change of the antenna signal radiated through the antenna array is the same for each frequency of the baseband signal having the same amplitude.

When the signal changing unit changes the baseband signal, the signal changing unit may be located between the baseband unit and the band converting unit.

When the signal changing unit changes the first band signal, the signal changing unit may be located between the band converting unit and the antenna array.

The signal changing unit may be implemented as at least one of a phase shifter, an amplifier, and an attenuator.

The plurality of antenna elements may include an active antenna element and a plurality of parasitic antenna elements, and the band converter may be a single RF chain.

The first band signal may be an intermediate frequency (IF) band signal or a radio frequency (RF) band signal.

According to another embodiment of the present invention, a baseband modulation apparatus is provided. The baseband modulator includes a baseband unit generating a baseband signal, an RF chain unit converting the baseband signal into a radio frequency (RF) band signal, and radiating through the antenna array for each frequency of each baseband signal. and a load calculator configured to calculate a first load value that is a load value of the plurality of antenna elements, and set the first load value to the antenna array so that at least one of a phase change and a magnitude change of the antenna signal to be used is the same there is.

The load calculator calculates a second load value that is a load value of the plurality of antenna elements by using the baseband signal, and at least one of a phase change and a magnitude change of the antenna signal is the same for each frequency of the baseband signal. to change the second load value to the first load value.

The plurality of antenna elements may include an active antenna element and a plurality of parasitic antenna elements, and the RF chain unit may be a single RF chain.

According to another embodiment of the present invention, there is provided a method for modulating a baseband signal in a beam space MIMO (Multi-Input Multi-Output) including a plurality of antenna elements. The baseband modulation method may include generating the baseband signal, converting the baseband signal into a first band signal having a frequency higher than a frequency of the baseband signal, and using the baseband signal, Calculating a load value of an antenna element of , and changing a phase or magnitude of the baseband signal or the first band signal in response to the frequency of the baseband signal.

The changing may include setting a change value for a phase or magnitude of the baseband signal or the first band signal in response to a frequency of the baseband signal, and corresponding to the change value, the baseband signal changing the signal or the first band signal.

The setting may include setting the change value so that the phase change or magnitude change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal.

The setting may include setting the change value so that the phase change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal having the same phase.

The setting may include setting the change value so that the size change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal having the same size.

The first band signal may be an intermediate frequency (IF) band signal or a radio frequency (RF) band signal.

According to an embodiment of the present invention, by changing the phase or magnitude of the baseband signal according to the frequency value, it is possible to compensate for the phase or magnitude of the baseband signal. Through this, normal channel estimation is possible even in beam space MIMO.

1 is a diagram illustrating a reactance variation value according to frequency for a variable impedance having an inductor component.
2 is a diagram illustrating a reactance variation value according to frequency for a variable impedance having a capacitor component.
3 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to an embodiment of the present invention.
4 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to another embodiment of the present invention.
5 is a flowchart illustrating a baseband signal modulation method in beam spatial MIMO according to an embodiment of the present invention.
6 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to another embodiment of the present invention.
7 is a flowchart illustrating a baseband signal modulation method in beam space MIMO according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, the embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. However, the present invention may be embodied in several different forms and is not limited to the embodiments described herein. And in order to clearly explain the present invention in the drawings, parts irrelevant to the description are omitted, and similar reference numerals are attached to similar parts throughout the specification.

Throughout the specification, a terminal is a mobile terminal (MT), a mobile station (MS), an advanced mobile station (AMS), a high reliability mobile station (HR-MS) ), a subscriber station (subscriber station, SS), a portable subscriber station (PSS), an access terminal (AT), user equipment (UE), and the like, and may refer to a terminal, MT, It may include all or some functions of AMS, HR-MS, SS, PSS, AT, UE, and the like.

In addition, the base station (base station, BS) is an advanced base station (advanced base station, ABS), a high reliability base station (high reliability base station, HR-BS), a Node B (node B), an advanced node B (evolved node B, eNodeB), an access point (AP), a radio access station (RAS), a base transceiver station (BTS), a mobile multihop relay (MMR)-BS, a relay serving as a base station station, RS), may refer to a high reliability relay station (HR-RS) that serves as a base station, etc., and may refer to ABS, NodeB, eNodeB, AP, RAS, BTS, MMR-BS, RS, HR It may include all or part of functions such as -RS.

A method and apparatus for modulating a baseband signal in beam space MIMO will now be described in detail.

In beam space MIMO, an orthogonal basis beam through which a baseband signal is transmitted is generated by decomposing a steering vector of a plurality of parasitic antenna elements, and the baseband signal is loaded on the basic beam. At this time, the steering vector of each antenna element is determined by the geometry of the antenna, and when the geometry of the antenna is changed, the steering vector of the antenna is also changed. The operation of loading the baseband signal to the base beam is performed by setting a current value flowing through each antenna (ie, parasitic antenna) with reference to the baseband signal. At this time, by changing the load value (the load value of the parasitic antenna), the value of the current flowing through each antenna is set. Since the load value has different characteristics for each frequency (the value of the variable impedance of the parasitic antenna changes according to the frequency), the phase or magnitude of the baseband signal may not be preserved.

FIG. 1 is a diagram illustrating a reactance variation value according to frequency for a variable impedance having an inductor component, and FIG. 2 is a diagram illustrating a reactance variation value according to frequency for a variable impedance having a capacitor component.

As shown in FIG. 1 , when the variable impedance by the parasitic antenna element has an inductor component, the value of the variable impedance increases in proportion to the frequency. and as shown in FIG. 2 . When the variable impedance by the parasitic antenna element has a capacitor component, the value of the variable impedance increases in inverse proportion to the frequency. That is, since the reactance component of the variable impedance varies according to the frequency, in beam space MIMO, it is necessary to compensate for the change in the phase or magnitude of the finally radiated antenna signal according to the frequency.

In order to solve this problem, a baseband signal modulation method and apparatus according to an embodiment of the present invention compensate for a change in phase or magnitude according to a frequency value. Such compensation may be made at the transmitting side. There are two methods for compensating for a phase or magnitude according to a frequency value. The first method is to change the signal itself, and the second method is to implement so that the frequency value of the load is as constant as possible at the target frequency.

The first method is a method of calculating the load value, calculating the phase or magnitude change with respect to frequency using the change in the load value according to frequency, and changing the corresponding signal to have the same phase change or magnitude change for each frequency.

The first method will be described with reference to FIGS. 3 to 5 .

3 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to an embodiment of the present invention.

As shown in FIG. 3 , in the beam space MIMO according to the embodiment of the present invention, the baseband signal modulation apparatus 100 includes a baseband unit 110 , a load calculator 120 , a signal change controller 130 , and a signal changer. It includes a unit 140 , a single RF chain unit 150 , and an antenna array 160 .

The baseband unit 110 generates a baseband signal to be transmitted. A method of generating a baseband signal by the baseband unit 110 is known to those of ordinary skill in the art to which the present invention pertains, so a detailed description thereof will be omitted.

The load calculator 120 calculates a load value for each antenna element (parasitic antenna element) included in the antenna array 160 by using the baseband signal. That is, the load calculator 120 calculates each load value corresponding to the baseband signal. The load calculation unit 120 sets the load value of the antenna array 160 in response to the calculated load value, through which the beam space MIMO technology can be implemented. A method for the load calculation unit 120 to calculate a load value using a baseband signal is known to those skilled in the art, and thus a detailed description thereof will be omitted.

The signal change control unit 130 receives the load value calculated by the load calculation unit 120 . The signal change controller 130 calculates the frequency performance of the input load value and sets the phase or magnitude change value so that the phase change or magnitude change is the same for each frequency of each baseband signal. Here, the frequency performance of the load value means a change in the reactance value of each antenna element (parasitic antenna element) with respect to each frequency. On the other hand, the signal change controller 130 does not calculate the frequency performance of the load value, but samples the frequency performance of the load value and sets the phase or magnitude change value so that the phase change or magnitude change is the same for each frequency of each baseband signal. there is.

Meanwhile, the load value calculated by the load calculator 120 and the load value actually implemented in the antenna array 160 may be different from each other. To this end, the signal change control unit 130 may receive the actual load value of the antenna array 160 and set the change value.

The signal change controller 130 controls the signal changer 140 to change the phase or magnitude of the baseband signal according to the set phase or magnitude change value. That is, the signal change control unit 130 according to the embodiment of the present invention sets the change value (phase or amplitude change value) so that the phase change or magnitude change for each frequency of each baseband signal is the same. Meanwhile, the signal change controller 130 calculates a phase difference according to frequency only for baseband signals having the same phase and sets the phase change value so that the phase difference (phase change) according to the frequency of the baseband signals having the same phase is constant. can In addition, the signal change controller 130 may calculate a magnitude ratio according to frequency only for baseband signals having the same magnitude and set the magnitude change value so that the magnitude ratio (change in magnitude) of the baseband signals having the same magnitude is constant.

The signal change unit 140 changes the phase or magnitude of the baseband signal under the control of the signal change control unit 130 . In order to change the phase, the signal changer 140 may be implemented as a phase shifter. And in order to change the size, the signal changing unit 140 may be implemented as an amplifier (amplifier) or an attenuator (attenuator). That is, the signal change unit 140 according to the embodiment of the present invention compensates the phase or magnitude of the baseband signal in response to the change value (phase or magnitude change value) set by the signal change controller 130 . Meanwhile, the signal change control unit 130 and the signal change unit 140 may be included in the baseband unit 110 . For this operation, when the baseband signal is a time signal, it is separated into each frequency signal through FFT (Fast Fourier Transform), and a phase or magnitude component to be changed is added to each frequency component. In addition, a signal to which a phase or magnitude component is added is converted into a time signal through Inverse Fast Fourier Transform (IFFT).

The single RF chain unit 150 forms one RF chain and converts a baseband signal whose magnitude or phase is changed into an RF band signal. Here, one RF chain may be implemented as a digital analog converter (DAC), a filter, an oscillator, or the like. On the other hand, the single RF chain unit 150 may be a small number of RF chains instead of one RF chain.

The antenna array 160 may include one active antenna and a plurality of parasitic antennas to generate a beam space MIMO signal. The antenna array 160 may be implemented through an ESPAR, a switched parasitic array (SPA), a load modulation antenna, or the like, and may have other structures to implement beam space MIMO. The antenna array 160 may set the load values of the plurality of parasitic antennas according to the load values calculated by the load calculator 120 .

Meanwhile, as a method of changing the signal itself as in the first method, it is possible to change the RF band signal instead of changing the baseband signal as in FIG. 3 . A method of changing the RF band signal in this way will be described with reference to FIG. 4 .

4 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to another embodiment of the present invention. FIG. 4 is the same as FIG. 3 except that changing the baseband signal changes the RF band signal.

As shown in FIG. 4 , in beam space MIMO according to another embodiment of the present invention, the baseband signal modulation apparatus 100 ′ includes a baseband unit 110 , a load calculation unit 120 , a signal change control unit 130 , It includes a signal changing unit 140 ′, a single RF chain unit 150 ′ and an antenna array 160 . Referring to FIG. 4 , unlike FIG. 4 , the signal changing unit 140 ′ is located at the rear end of the single RF chain unit 150 ′.

The baseband unit 110 generates a baseband signal to be transmitted.

The load calculator 130 calculates a load value for each antenna element (parasitic antenna element) included in the antenna array 160 by using the baseband signal.

The signal change control unit 130 receives the load value calculated by the load calculation unit 120, calculates the frequency performance of the received load value, so that the phase change or magnitude change is the same for each frequency of each baseband signal. Set the size change value.

The single RF chain unit 150' converts a baseband signal into an RFband signal. Here, the single RF chain unit 150 ′ may include an IF band converter (not shown) that converts a baseband signal into an IF (Intermediate Frequency) band signal. When the single RF chain unit 150' includes an IF band converter, the single RF chain unit 150' converts the IF band signal into an RF band signal. In this case, the IF band signal and the RF band signal have high frequencies as the frequency of the baseband signal. Accordingly, the single RF chain unit 150' and the IF band converter may be collectively referred to as a band converter.

The signal change unit 140 ′ changes the phase or magnitude of the RF band signal (symbol) under the control of the signal change controller 130 . Meanwhile, the signal change unit 140 ′ may change the phase or magnitude of the IF band under the control of the signal change controller 130 . Hereinafter, it will be described that the phase or magnitude of the RF band signal is changed for convenience of description, but the phase or magnitude of the IF band signal may be changed instead of the RF band signal.

The antenna array 160 may include one active antenna and a plurality of parasitic antennas to generate a beam space MIMO signal. The antenna array 160 may set the load values of the plurality of parasitic antennas according to the load values calculated by the load calculator 120 .

Meanwhile, in FIGS. 3 and 4 , only one of a phase or a magnitude may be changed, or both a phase and a magnitude may be changed. At this time. When only the phase is changed, the signal changer 140 may be implemented only as a phase shifter, and when only the magnitude is changed, the signal changer 140 may be implemented only as an amplifier or an attenuator.

And in FIG. 4 , the signal changing unit 140 ′ is included in the single RF chain unit 150 , and may change the RF band signal within the single RF chain unit 150 .

5 is a flowchart illustrating a baseband signal modulation method in beam spatial MIMO according to an embodiment of the present invention.

First, the load calculator 120 calculates a load value using the baseband signal (S510). The load calculator 120 calculates a load value of each parasitic antenna (parasitic antenna of the antenna array 160) corresponding to the baseband signal.

The signal change controller 130 sets the phase or magnitude change value so that the phase change or magnitude change for each frequency of each baseband signal is the same by using the load value calculated in step S510 ( S520 ). That is, the signal change control unit 130 sets the change value (phase or amplitude change value) so that the phase change or magnitude change with respect to the signal finally radiated through the antenna for each frequency of each baseband signal is the same. Meanwhile, the signal change controller 130 may calculate a phase change (difference) in frequency only for baseband signals having the same phase and set the phase change value so that the phase change according to the frequency of the baseband signals having the same phase is constant. . In addition, the signal change controller 130 may calculate a magnitude change (magnitude ratio) according to frequency only for baseband signals having the same magnitude and set the magnitude change value so that the magnitude change of the baseband signals having the same magnitude is constant.

The signal changer 140 or 140' changes the phase or magnitude of the baseband signal or the RF band signal by using the change value set in step S520 (S530).

As described above, the baseband signal (or RF band signal) whose phase or magnitude is compensated is finally input to the antenna array 160 , thereby compensating for a change in phase or magnitude according to frequency.

Hereinafter, with reference to FIGS. 6 and 7 , a second method, a method of applying an additional condition to the load value calculation, will be described.

The second method is to add a condition for the phase or magnitude according to the frequency when calculating the load value so that the frequency value of the rod is as constant as possible at the target frequency.

6 is a diagram illustrating an apparatus for modulating a baseband signal in beam space MIMO according to another embodiment of the present invention, and FIG. 7 is a flowchart illustrating a method for modulating a baseband signal in beam space MIMO according to another embodiment of the present invention. am.

As shown in FIG. 6 , in the beam space MIMO according to another embodiment of the present invention, the baseband signal modulation apparatus 100'' includes a baseband unit 110, a load calculator 120'', and a single RF chain unit. 150 and an antenna array 160 .

The baseband unit 110 generates a baseband signal to be transmitted.

The load calculator 120 ″ calculates a load value for each antenna element included in the antenna array 160 using a baseband signal. In this case, the load calculation unit 120'' applies an additional condition to the load value calculation. This additional condition provision method will be described with reference to FIG. 7 as follows.

First, the load calculator 120'' calculates a first load value using the baseband signal (S710). Here, the first load value refers to a load value that considers only the baseband signal without considering a change in phase or magnitude. When only the first load value is set in the antenna array 160 , the phase or magnitude of each baseband signal may be changed for each frequency. To compensate for this, the load calculator 120'' changes the first load value to the second load value so that the phase change or magnitude change for each frequency of each baseband signal is the same (S720). Here, when the phase or magnitude does not need to be changed, the second load value may be the same as the first load value. Then, the load calculator 120 ″ sets the second load value to the antenna array 160 ( S730 ). That is, the second load value is finally set as the load value of the antenna array 160 , so that it is possible to compensate for a phase or magnitude change according to a frequency that may occur in beam space MIMO.

The single RF chain unit 150 converts a baseband signal into an RFband signal. In addition, the antenna array 160 may include one active antenna and a plurality of parasitic antennas. In this case, the antenna array 160 may set the load values of the plurality of parasitic antennas according to the second load values calculated by the load calculator 120 .

In the above description, the case in which the phase of the baseband signal needs to be compensated is the case in which information is transmitted through the phase. A typical example is a phase shift keying (PSK) modulation scheme. The case in which the magnitude of the baseband signal needs to be compensated is when information is transmitted through the magnitude. A typical example is an Amplitude Shift Keying (ASK) modulation scheme. In addition, the case in which both the magnitude and phase of the baseband signal must be preserved is a case in which information is transmitted through magnitude and phase. A typical example is a Quadrature Amplitude Modulation (QAM) method.

In the case of the ASK modulation method, information can be transmitted without compensating for phase information. And in the case of the PSK modulation method, information can be transmitted without compensating for size information. However, in the case of the size, there is a limit to the capacity of the power amplifier, so even the PSK method may be limited so that it does not exceed a certain size depending on the situation.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements by those skilled in the art using the basic concept of the present invention as defined in the following claims are also provided. is within the scope of the right.

Claims (18)

An antenna array comprising a plurality of antenna elements and radiating a beam space MIMO (Multi-Input Multi-Output) signal;
a baseband portion for generating a baseband signal;
a band converter converting the baseband signal into a first band signal having a higher frequency than that of the baseband signal;
a load calculator that receives the baseband signal, calculates load values of the plurality of antenna elements using the received baseband signal, and sets the calculated load values in the antenna array;
a signal change controller configured to set a change value for at least one of a phase and a magnitude of the baseband signal in response to the frequency of the baseband signal; and
and a signal changing unit configured to change at least one of the baseband signal and the first band signal in response to the change value. According to claim 1,
The signal change controller is configured to set the change value so that at least one of a phase change and a magnitude change of an antenna signal radiated through the antenna array for each frequency of each baseband signal is the same. According to claim 1,
The signal change controller is configured to set the change value so that the phase change of the antenna signal radiated through the antenna array is the same for each frequency of the baseband signal having the same phase. According to claim 1,
The signal change controller is configured to set the change value so that the amplitude change of the antenna signal radiated through the antenna array is the same for each frequency of the baseband signal having the same amplitude. According to claim 1,
When the signal changing unit changes the baseband signal, the signal changing unit is positioned between the baseband unit and the band converting unit. According to claim 1,
When the signal changing unit changes the first band signal, the signal changing unit is located between the band converting unit and the antenna array. According to claim 1,
The signal changing unit is a baseband modulation device implemented by at least one of a phase shifter, an amplifier, and an attenuator. According to claim 1,
The plurality of antenna elements includes an active antenna element and a plurality of parasitic antenna elements,
The band converter is a single RF chain baseband modulator. According to claim 1,
The first band signal is an intermediate frequency (IF) band signal or a radio frequency (RF) band signal. delete delete delete A method of modulating a baseband signal in a beam space MIMO (Multi-Input Multi-Output) including a plurality of antenna elements, the method comprising:
generating the baseband signal;
converting the baseband signal into a first band signal having a higher frequency than a frequency of the baseband signal;
receiving the baseband signal and calculating load values of the plurality of antenna elements by using the received baseband signal; and
and changing a phase or magnitude of the baseband signal or the first band signal in response to the frequency of the baseband signal. 14. The method of claim 13,
The changing step is
setting a change value for a phase or magnitude of the baseband signal or the first band signal in response to the frequency of the baseband signal; and
and changing the baseband signal or the first band signal in response to the change value. 15. The method of claim 14,
The setting may include setting the change value so that the phase change or magnitude change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal. 15. The method of claim 14,
The setting includes setting the change value so that the phase change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal having the same phase. 15. The method of claim 14,
The setting includes setting the change value so that the amplitude change of the antenna signals radiated through the plurality of antenna elements is the same for each frequency of the baseband signal having the same amplitude. 14. The method of claim 13,
The first band signal is an intermediate frequency (IF) band signal or a radio frequency (RF) band signal.

Images