KR20190099876A - Frequency synthesizer using manifold coupled multiplexer - Google Patents

Abstract

A broadband high speed frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention comprises: a direct frequency synthesizer module for outputting signals within a specific frequency band; and the manifold coupled multiplexer having a plurality of filters ramifying the signals output from the direct frequency synthesizer module into n (n is an integer of 2 or more) channel lines and filtering the signals of each channel line into different bands, and coupled with rear ends of each channel line to multiplex the signals output from each channel line. According to the present invention, broadband frequency properties can be effectively improved by preventing discontinuous points in phase properties of continuous signals in overlapped bands of each channel.

Description

Frequency synthesizer using manifold coupled multiplexer}

The present invention relates to a frequency synthesizer using a manifold-coupled multiplexer, and more particularly, by using a manifold-coupled multiplexer, it is possible to effectively prevent discontinuities in the phase characteristics of continuous signals in the overlapping band of each channel. It is possible to improve the wideband frequency characteristics and thus to a wider frequency synthesizer with a wider width between the minimum and maximum frequency signals that can be output.

A frequency synthesizer is a device that generates an output signal of various frequencies by converting a reference signal. Types of such frequency synthesizers include indirect frequency synthesizers and direct digital synthesizers (DDS).

The indirect frequency synthesizer uses a phase lock loop (PLL), which detects the phase difference between a reference signal at the input stage and an output signal at the output stage with a PLL, and then detects the voltage value through a filter. And outputs an output signal having a frequency corresponding to the corresponding voltage value through a voltage controlled oscillator (VCO). In this case, the indirect frequency synthesizer inputs an output signal back to the phase detector through a feedback loop, and may output an output signal having a desired frequency by adjusting the division ratio of the divider in the feedback loop.

However, since the indirect frequency synthesizer uses a phase lock loop (PLL), a direct digital synthesizer with excellent frequency conversion speed performance and frequency resolution performance has been developed because the frequency conversion speed is slow and precise frequency adjustment is difficult.

1 shows a general block diagram of a direct digital synthesizer.

As shown in FIG. 1, the direct digital synthesizer includes a phase accumulator (PA), a phase-to-sine converter (PSC), and a DC-to-AC converter (DAC). converter, and a low pass filter (LPF), the operation of which is as follows.

That is, the phase accumulator PA outputs appropriate phase information for every clock of the reference signal CLK _R according to the frequency information F _CW received from the outside. Thereafter, the phase-sine converter (PSC) outputs amplitudes of a sine function and a cosine function corresponding to the input phase information. At this time, the phase-sine converter (PSC) calculates the sine and cosine values by using a CORDIC (Coordinated Rotation Digital Computer) method using iterative operation, a ROM (Read-Only Memory) method which stores function values in advance, and linear interpolation. (interpolation) technique. Then, the DC-AC converter converts the digital value output from the phase-sine converter (PSC) into an analog value, and the low pass filter (LPF) finally outputs a signal having a constant frequency by filtering the value. do.

On the other hand, radar systems and the like (hereinafter, broadband use systems) output signals of high resolution frequencies (including DAC Time Resolutions of 5 kHz or less) such as the Ka band of 26.5 kHz to 40 kHz, with the minimum frequency signal and maximum output possible. There is a need for a wideband (e.g., 1 Hz or more) frequency synthesizer with a wide width (hereinafter referred to as "bandwidth") between frequency signals. However, the conventionally developed direct digital synthesizer could not satisfy this requirement.

Therefore, in order to satisfy the requirements of the broadband use system, a frequency synthesizer in which multiple frequency multipliers and mixers are combined to one direct digital synthesizer module provided in a modular form can be derived. However, these frequency synthesizers must be provided with a large number of multipliers and mixers due to the limited bandwidth of one direct digital synthesizer module itself. That is, in the case of such a frequency synthesizer, problems such as an increase in signal loss, an increase in an undesired wave level, and a deterioration of phase mismatch due to an increase in the number of times of multiplication and mixing have occurred.

To solve this problem, it is possible to derive a technique to overcome the bandwidth limitation by changing the internal configuration of one direct digital synthesizer module itself. However, since this technique corresponds to a technique for changing the internal configuration of a conventionally manufactured direct digital synthesizer module, another problem arises in that the manufacturing cost according to the new process is increased.

In order to solve the problems of the prior art as described above, the present invention by connecting a manifold-coupled multiplexer to a conventional direct digital synthesizer module to output a wideband signal, a continuous signal in the overlapping band of each channel Discontinuity can be avoided in the phase characteristics of the system, which not only improves the broadband frequency characteristics efficiently but also reduces the number of additionally connected frequency multipliers and mixers to a minimum, thereby reducing signal loss, unwanted wave levels, and phase. The purpose is to provide a wideband frequency synthesizer that can minimize noise degradation.

However, the problem to be solved by the present invention is not limited to the above-mentioned problem, another task that is not mentioned will be clearly understood by those skilled in the art from the following description.

Frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention for solving the above problems, (1) from the direct frequency synthesizer module for outputting a signal in a specific frequency band, (2) from the direct frequency synthesizer module Branches the output signal into n channel lines (where n is a natural number of 2 or more), and includes a plurality of filters for filtering the signals of each channel line into different bands, and multiplexing signals output from each channel line. And a manifold coupled multiplexer having a rear end coupled to each channel line.

The signal pass band of each channel line implemented by one or more filters connected to each channel line may be different from each other, and k-th pass signal passing through the k-th channel line (where k is a natural number between 1 and n-1). The minimum frequency of may be equal to the maximum frequency of the k + 1 th passing signal through the k + 1 th channel line.

The frequency of the second harmonic relative to the minimum frequency of the k + 1 th pass signal may be included in the signal pass band of the k th channel line.

The signal passing bandwidth B _{k k} of the k th channel line may satisfy the following equation.

(expression)

BW _K = 2F _MIN Ⅹ C _BW

(F _MIN is the minimum frequency of the k th pass signal, C _BW is the bandwidth adjustment factor, a value less than 1)

In the case where n is 2, the manifold-coupled multiplexer includes: (1) a first upper end of which the signal output from the direct frequency synthesizer module is input into one end, the other end is connected to the first branch node, and the high pass cutoff frequency is F ₁ MHz; Low pass filter, (2) one end connected to the first branch node, the first top high pass filter with a low cutoff frequency of F ₂ MHz, and (3) one end connected to the other end of the first top high pass filter, the other end A first lower high pass filter connected to the first coupling node and having a low cutoff frequency of F ₂ MHz, (4) one end of which is connected to the first coupling node, and the multiplexed output signal is output to the other end, and the high frequency cutoff frequency A first lower low pass filter having F ₁ MHz, (5) one end connected to the first branch node, a second upper low pass filter having a high cutoff frequency of F ₂ MHz, and (6) one end of a second upper low pass filter Connected to the other end of the filter, the low cutoff frequency of F ₃ ㎒ A second upper high pass filter, (7) a second lower high pass filter having one end connected to the other end of the second upper high pass filter, and having a low cutoff frequency of F ₃ MHz, and (8) one end of a second lower high pass filter And a second lower low pass filter connected to the other end of the second end and connected to the first coupling node, and having a high cutoff frequency of F ₂ MHz.

In the case where n is 3 or more, the manifold-coupled multiplexer includes: (1) a first signal output from the direct frequency synthesizer module into one end, the other end connected to the first branch node, and a high frequency cutoff frequency of F ₁ MHz; An upper low pass filter, (2) one end connected to a first branch node, a first upper high pass filter having a low cutoff frequency of F ₂ MHz, and (3) one end connected to the other end of the first upper high pass filter, A first lower high pass filter having the other end connected to the first coupling node, the low pass cutoff frequency of F ₂ MHz, (4) one end connected to the first coupling node, and the multiplexed output signal being output to the other end, A first lower low pass filter having a frequency of F ₁ MHz, (5) one end of which is connected to the j-1th branch node (where j is 2 to n-1), the other end of which is connected to the jth branch node, the cut-off frequency F _j of the j-th ㎒ top of the low-pass filter, and (6) one end of the j-th branch town Is connected to, the low cut-off frequency is F _{j + 1} ㎒ of the j-th upper high-pass filter, and (7) once the first and j connected to the other terminal at the top of the high-pass filter, and the other end is connected to the j-th combination word, a low blocking _J- th lower high pass filter with frequency F _{j + 1} MHz, (8) j-th end connected to j-th coupling node, the other end to j-1 coupling node, j-high frequency cutoff frequency _{j j} MHz Bottom low pass filter, (9) one end connected to n-th branch node, n-th top low pass filter with high cut-off frequency F _n MHz, and (10) one end connected to the other end of n-th top low pass filter An _n- th top high pass filter having a low cutoff frequency of F _{n + 1} ㎒, (11) one end of which is connected to the other end of the n-th top high pass filter, and an _n- th lower high pass having a low cutoff frequency of F _{n + 1} MHz Pass filter, (12) one end of which is connected to the other end of the nth lower high pass filter, and the other end of which is connected to the n-1 coupling node , The high-band cut-off frequency may comprise a second lower low-pass filter, F _n ㎒.

The magnitude of the frequency may decrease in the order of F ₁ to F _{n + 1} .

Broadband high-speed frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention, (1) a plurality of frequency multipliers connected in turn to the output of the manifold coupled multiplexer, (2) the front or rear end of the frequency multiplier It may be further connected to, and may further include one or more mixers for raising the frequency band of the signal.

The bandwidth of the final output signal multiplied by the plurality of frequency multipliers may be 1 kHz or more.

The frequency band of the final output signal raised through the mixer and the plurality of frequency multipliers is C band band, X band band, Ka band band, Ku band band, K band band, V band band, W band band and M band band. It may be any one of.

The present invention is configured as described above by connecting a manifold-coupled multiplexer to a conventional direct digital synthesizer module to output a wideband signal, thereby preventing discontinuities in the phase characteristics of the continuous signal in the overlapping band of each channel In addition to improving broadband frequency characteristics efficiently, the number of additionally connected multipliers and mixers can be reduced to a minimum, thereby minimizing signal loss, unwanted level and phase noise degradation, and manufacturing. You can also save money.

In addition, the present invention can easily perform a sweeping operation for sequentially outputting between the minimum frequency and the maximum frequency for all the required frequency bands that are wideband, which is useful for a radar system or the like requiring a wideband chirp signal.

In addition, the present invention can effectively eliminate unwanted waves, such as second harmonics, for the pass signal of each channel line by suggesting a proper signal passband setting method for each channel line of the manifold-coupled multiplexer.

In addition, the present invention outputs a signal that satisfies the conditions such as the frequency band of the Ka band band, the bandwidth of 1 GHz or more, DAC Time Resolutions of 5 GHz or less required for a broadband use system such as a radar system, but the minimum number of frequency multipliers And a corresponding signal using the number of mixers.

1 shows a general block diagram of a direct digital synthesizer.
2 shows a structure of a frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention.
3 shows a conventional manifold coupled multiplexer.
4 shows a manifold coupled multiplexer 3 with two channel lines according to one embodiment of the invention.
5 shows a three channel manifold coupled multiplexer 3 according to one embodiment of the invention.
6 shows the frequency band and bandwidth of a signal passing through filters connected to the channel line in a frequency synthesizer using a manifold coupled multiplexer 3 with three channel lines according to an embodiment of the invention.
7 illustrates a frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention further comprising a plurality of frequency multipliers 20 and a mixer 30.

The above objects, means, and effects thereof will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, and as a result, those skilled in the art to which the present invention pertains may easily facilitate the technical idea of the present invention. It can be done. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted.

Also, the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. In this specification, the singular forms also include the plural forms as the case otherwise indicates. As used herein, the terms "comprise," "comprise," "presume" or "have" do not exclude the presence or addition of one or more components other than the components mentioned.

In this specification, expressions such as “or”, “at least one,” and the like may represent one of the words listed together or a combination of two or more. For example, “A or B”, “at least one of A and B” may include only one of A or B, and may include both A and B.

In this specification, descriptions according to expressions such as “for example” may not exactly match the information presented, such as the recited characteristics, variables, or values, and are typical of tolerances, measurement errors, and limits of measurement accuracy. Embodiments of the invention according to various embodiments of the present invention should not be limited to such effects as modifications including other factors.

In the present specification, when a component is referred to as being 'connected' or 'connected' to another component, it may be directly connected to or connected to the other component, but another component may be It should be understood that it may exist. On the other hand, when a component is said to be 'directly connected' or 'directly connected' to another component, it should be understood that there is no other component in between.

Unless otherwise defined, all terms used in the present specification may be used in a sense that can be commonly understood by those skilled in the art. Moreover, the terms defined in the commonly used dictionaries are not ideally or excessively interpreted unless they are specifically defined clearly.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 shows a structure of a frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention.

A frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention, as shown in FIG. 2, includes a synthesizer 10. At this time, the synthesizer 10 is a configuration for outputting a wideband signal using a manifold coupled multiplexer, the reference signal generator 1, the direct frequency synthesizer module 2 and the manifold coupled multiplexer 3 (MCM: Manifold Coupled Multiplexer).

A reference signal generator 1 generates a reference clock signal (CLK _R), the generated reference clock signal (CLK _R) are input directly to the digital synthesizer module (2).

The direct frequency synthesizer module 2 provides a function of a direct digital synthesizer. The direct frequency synthesizer module 2 outputs a signal of a specific frequency band using an input reference clock signal CLK _R and frequency information F _CW . In this case, the frequency information F _CW may include information on the frequency of the signal to be output and may be directly input to the frequency synthesizer module 2 through an external separate device or an internal control unit (not shown).

For example, the direct frequency synthesizer module 2, as shown in FIG. 1, the direct digital synthesizer, as shown in FIG. 1, a phase accumulator (PA), a phase-sine converter (PSC) : May include, but are not limited to, a phase-to-sine converter (DAC), a digital-to-analog converter (DAC), and a low pass filter (LPF).

The direct frequency synthesizer module 2 may output a signal having any frequency among the frequencies of F _S to F _E. In this case, F _S is the minimum frequency, F _E is the maximum frequency. However, as the frequency of the output signal is higher, the direct digital synthesizer module 2 may generate various unwanted waves. Therefore, among the signals output from each direct digital synthesizer module 2, the maximum frequency F _E is the internal clock signal of the direct digital synthesizer module 2 so that the digital synthesizer module 2 can operate within an appropriate SFDR. Less than or equal to the frequency of is preferable.

For example, the digital synthesizer module 2 can be implemented directly with the AD9910 module from ADI. At this time, the internal clock signal of the AD9910 is 225 MHz, and the SFDR deteriorates rapidly when a signal of 250 MHz or more is output. Therefore, when implemented with the AD9910, it is preferable that the maximum frequency F _E of the signals of the plurality of direct digital synthesizer modules 2 is 225 MHz or less.

Various undesired waves may occur when F _S to F _E is greater than or equal to a certain width, that is, even when the direct frequency synthesizer module 2 processes a wideband signal. Therefore, in order to eliminate such unwanted waves, a configuration capable of filtering the wideband signal output from the direct frequency synthesizer module 2 is needed, and the manifold coupled multiplexer 3 plays this role. Can be done.

3 shows a conventional manifold coupled multiplexer.

A conventional manifold coupled multiplexer (MCM) includes a plurality of channel lines CL and a channel filter CF, and filters a plurality of input signals and outputs them as one output signal. At this time, each channel line CL receives each input signal Input as its input terminal, and the rear ends thereof are coupled to each other. In addition, each channel filter CF is provided in each channel line CL and implemented as a band pass filter (BPF) for passing different frequency bands. That is, each channel line CL receives a specific input signal and filters the specific input signal to output a signal of a specific frequency band, and outputs a final output signal by combining the filtered signals at a later stage. do.

Such a conventional manifold coupled multiplexer (MCM) has the advantage of processing a wide bandwidth signal while minimizing unnecessary waves. In order to take advantage of these advantages, the present invention provides a manifold coupled multiplexer ( Include 3).

However, since a conventional manifold coupled multiplexer (MCM) receives and filters a plurality of input signals and outputs them as one output signal, a plurality of input terminals are implemented. However, in the present invention, since one input signal is input, filtered, and output as one output signal, it is necessary to change the configuration of a conventional Manifold Coupled Multiplexer (MCM).

4 shows a manifold coupled multiplexer 3 with two channel lines according to one embodiment of the invention. 5 shows a manifold coupled multiplexer 3 with three channel lines according to one embodiment of the invention.

That is, referring to FIGS. 4 and 5, the manifold coupled multiplexer 3 according to an embodiment of the present invention has n input signals output from the direct frequency synthesizer module 2 (where n is Branches to channel lines CL ₁ ,... CL _n of two or more natural numbers). Through this branching configuration, the manifold coupled multiplexer 3 can divide one input signal into a plurality of channel signals. At this time, the manifold coupled multiplexer 3 is provided with a plurality of filters branched to each channel line CL ₁ ,... CL _n to filter the input channel signal into different bands. In this case, when the filter is implemented as a band pass filter (BPF), not only the configuration is complicated but also the implementation cost may be expensive. Therefore, the filter is preferably implemented with a low pass filter (LPF) and a high pass filter (HPF).

As a plurality of filters are filtered to different bands, signals output through each channel line CL ₁ ,... CL _n have different frequency bands. In addition, the manifold coupling multiplexer 3 couples the rear ends of each channel line CL ₁ ,... CL _n to multiplex the channel signal output from each channel line CL.

When n is 2, as shown in FIG. 4, the manifold coupled multiplexer 3 includes a first top low pass filter LPF _1a , a first top high pass filter HPF _1a , and a first bottom high pass filter. (HPF _1b ), first lower low pass filter (LPF _1b ), second upper low pass filter (LPF _2a ), second upper high pass filter (HPF _2a ), second lower high pass filter (HPF _2b ), and first 2 The lower low pass filter (LPF _2b ) is included (hereinafter, for convenience of explanation, these filters are to be indicated only by symbols in the description, but the signal input stage is referred to as “one stage” and the signal output stage “ Other end ”. In this case, for impedance matching, the upper filters and the lower filters are provided to be symmetrical to each other.

That is, the filters connected to the first channel line CL ₁ are LPF _1a , LPF _2a , HPF _1a , HPF _1b , LPF _1b, and LPF _2b . At this time, the first LPF _1a, which are filters that are connected to the upper end of the channel line (CL ₁₎ LPF _2a and HPF _1a, a first channel line (CL ₁₎ HPF _1b, which are filters that are connected to the lower end of the LPF _1b and LPF _2b Are arranged symmetrically with each other, LPF _1a has the same filtering characteristics as LPF _1b , HPF _1a is HPF _1b , LPF _2a and LPF _2b , respectively.

In addition, the filters connected to the second channel line CL ₂ are LPF _2a , HPF _2a , HPF _2b and LPF _2b . At this time, LPF _2a and HPF _1a , which are filters connected to the upper end of the second channel line CL ₂ , and HPF _2b and LPF _2b, which are filters connected to the lower end of the first channel line CL ₁ , are arranged to be symmetric with each other. and, LPF _2a and _2b is a LPF, HPF _2a has the same filter characteristics as HPF _2b, respectively.

However, "the same filtering characteristic" means that the high cutoff frequencies are the same or within a certain error range in case of LPFs, and that the low cutoff frequencies are the same or within a certain error range in case of HPF. it means.

At one end of the LPF _1a, a signal output from the frequency synthesizer module 2 is input, and the other end thereof is connected to the first branch node DN ₁ . At this time, the high frequency cutoff frequency of the LPF _1a is F ₁ MHz.

The HPF _1a is provided directly on the first channel line CL ₁ , and one end thereof is connected to the first branch node DN ₁ . At this time, the low cutoff frequency of HPF _1a is F ₂ MHz.

The HPF _1b is provided directly on the first channel line CL ₁ , _one end of which is connected to the other end of the HPF _{1a, and} the other end of which is connected to the first coupling node CN ₁ . At this time, the low cutoff frequency of HPF _1b is F ₂ MHz.

One end of the LPF _1b is connected to the first coupling node CN1, and the multiplexed output signal is output to one end via the first coupling node CN1. At this time, the high cutoff frequency of LPF _1b is F ₁ MHz.

The LPF _2a has one end connected to the first branch node DN ₁ . At this time, the high cutoff frequency of LPF _2a is F ₂ MHz.

The HPF _2a is provided directly on the second channel line CL ₂ , and one end thereof is connected to the other end of the LPF _2a . At this time, the low cutoff frequency of HPF _2a is F ₃ MHz.

HPF _2b is provided directly on the second channel line CL ₂ , one end of which is connected to the other end of HPF _2a . At this time, the low cutoff frequency of HPF _2b is F ₃ MHz.

One end of the LPF _2b is connected to the other end of the HPF _{2b, and} the other end thereof is connected to the first coupling node CN ₁ . At this time, the high frequency cutoff frequency of LPF _2b is F ₂ MHz.

F ₁ , F _2, and F ₃ are different frequencies, and the frequencies decrease in order from F ₁ to F ₃ . According to the configuration of the filter described above, the signal passing through the first channel line CL ₁ may have a frequency band between F ₂ and F ₁ , and may have a bandwidth BW ₁ as much as F ₁ -F ₂ . have. In addition, the signal passing through the second channel line CL ₂ may have a frequency band between F ₃ and F ₂ , and may have a bandwidth BW ₂ as much as F ₂ -F ₃ . Therefore, the signal output from the manifold coupled multiplexer ₃ may have a frequency band between F ₃ and F ₁ , and may have an overall bandwidth BW _T by F ₁ -F ₃ . In this case, BW ₁ and BW ₂ may have different sizes. Also, F ₃ is equal to F _S or F, and _S may be greater than, F ₁ may be less than or equal to F _E F _E.

On the other hand, when n is 3 or more, as shown in FIG. 5, the manifold coupled multiplexer 3 includes a first top low pass filter LPF _1a , a first top high pass filter HPF _1a , and a first bottom High pass filter (HPF _1b ), first lower low pass filter (LPF _1b ), second upper low pass filter (LPF _2a ), jth upper low pass filter (LPF _ja ), where j is 2 to n-1 ), Jth top high pass filter (HPF _ja ), jth bottom high pass filter (HPF _jb ), jth bottom low pass filter (LPF _jb ), jth top low pass filter (LPF _ja ), nth top high pass Includes a pass filter (HPF _na ), an n th lower high pass filter (HPF _nb ), and an n th lower low pass filter (LPF _nb ) (hereinafter, for convenience of description, these filters are denoted only by symbols in the description, The stage where the signal is input is called "one end" and the stage where the signal is output is called "the other end." At this time, considering the impedance matching and the bandwidth of each channel, the upper filter and the lower filter is provided to be symmetrical to each other.

That is, the filters connected to the first channel line CL ₁ are LPF _1a , LPF _2a , HPF _1a , HPF _1b , LPF _1b, and LPF _2b . At this time, the first LPF _1a, which are filters that are connected to the upper end of the channel line _{(CL 1) LPF 2a, HPF} 1a , a first channel line (CL ₁₎ HPF _1b, which are filters that are connected to the lower end of the LPF _1b and LPF _2b Are arranged symmetrically with each other, LPF _1a has the same filtering characteristics as LPF _1b , HPF _1a is HPF _1b , LPF _2a and LPF _2b , respectively.

Also, the filters connected to the _j th channel line CL _j are LPF _ja , LPF _{(j + 1) a} , HPF _ja , HPF _jb , LPF _jb and LPF _{(j + 1) b} . At this time, LPF _ja , LPF _{(j + 1) a} and HPF _ja , which are connected to the top of _j- th channel line CL _j , HPF _jb , which are connected to the bottom of _j- th channel line CL _j , LPF _jb and LPF _{(j + 1) b} are arranged symmetrically with each other, LPF _ja for LPF _jb , HPF _ja for HPF _jb , and LPF _{(j + 1) a} equal to LPF _{(j + 1) b} , respectively. It has filtering characteristics.

In addition, the filters connected to the _n- th channel line CL _n are LPF _na , HPF _na , HPF _nb, and LPF _nb . At this time, the n-channel line (CL _n) LPF _na and HPF _na and a second n-channel line (CL _n) arranged filter which are HPF _nb and LPF _nb connected to the lower end is to be symmetrical to each other of which are filters that are connected to the top of the and, LPF is _na and _nb LPF, HPF _na have the same filter characteristics as HPF _nb, respectively.

The connection configuration of LPF _1a , HPF _1a , HPF _1b and LPF _1b is the same as described in the case where n is 2, and thus will be omitted.

One end of the LPF _ja is connected to the _j- 1th branch node DN _j-1 , and the other end thereof is connected to the jth branch node DN _j . The high cutoff frequency of LPF _ja is F _j MHz.

The HPF _ja is provided directly on the _j- th channel line CL _j , and one end thereof is connected to the _j- th branch node DN _j . At this time, the low cutoff frequency of HPF _ja is F _{j + 1} MHz.

The HPF _jb is provided directly on the _j- th channel line CL _j , one end of which is connected to the other end of the HPF _{ja, and} the other end of which is connected to the j-th coupling node CN _j . At this time, the low cutoff frequency of HPF _jb is F _{j + 1} MHz.

One end of the LPF _jb is connected to the _j th coupling node CN _j and the other end thereof is connected to the j th coupling node CN _j-1 . At this time, the high frequency cutoff frequency of LPF _jb is F _j MHz.

One end of the LPF _na is connected to the _{n−1 th} branch node DN _n−1 . At this time, the high frequency cutoff frequency of LPF _na is F _n MHz.

HPF _na is provided directly on the nth channel line CL _n , and one end thereof is connected to the other end of the LPF _na . At this time, the low cutoff frequency of HPF _na is F _{n + 1} MHz.

HPF _nb is provided directly on the _n- th channel line CL _n , and one end thereof is connected to the other end of HPF _na . At this time, the low cutoff frequency of HPF _nb is F _{n + 1} MHz.

One end of the LPF _nb is connected to the other end of the HPF _{nb, and} the other end thereof is connected to the n-th coupling node CN _n-1 . At this time, the high cutoff frequency of LPF _nb is F _n MHz.

F ₁ to F _{n + 1} are different frequencies, and the magnitude of the frequencies decreases in the order of F ₁ to F _{n + 1} . According to the configuration of the filter described above, the signal passing through the first channel line CL ₁ may have a frequency band between F ₂ and F ₁ , and may have a bandwidth BW ₁ as much as F ₁ -F ₂ . In addition, the signal passing through the _j th channel line CL _j may have a frequency band between F _{j + 1} and F _j , and may have a bandwidth BW _j equal to F _j −F _{j + 1} . . In addition, the signal passing through the _n th channel line CL _n may have a frequency band between F _{n + 1} and F _n , and may have a bandwidth BW _n equal to F _n −F _{n + 1} . Therefore, the signal output from the manifold coupled multiplexer 3 may have a frequency band between F _n and F ₁ , and may have a total bandwidth BW _T by F ₁ -F _n . In this case, BW ₁ to BW _n may have a different size. In addition, F _n can be greater than or equal to F _S F _S, F ₁ may be less than or equal to F _E F _E.

6 shows the frequency band and bandwidth of a signal passing through filters connected to the channel line in a frequency synthesizer using a manifold coupled multiplexer 3 with three channel lines according to an embodiment of the invention.

Referring to FIG. 6, signal passbands of each channel line CL implemented by one or more filters connected to each channel line CL are different from each other. In this case, the k + 1 th passing signal passing through the k + 1 th channel line CL _k (where k is a natural number between 1 and n-1) (that is, the signal of the output terminal portion of the k + 1 th channel line) The minimum frequency of is equal to the maximum frequency of the k th pass signal passing through the _k th channel line CL _k (ie, the signal at the output end portion of the k th channel line) (hereinafter referred to as “first condition”).

As the first condition is provided, the frequency synthesizer using the manifold-coupled multiplexer 3 according to an embodiment of the present invention sweeps sequentially outputting between the minimum frequency and the maximum frequency for the entire required frequency band which is wideband. There is an advantage that the sweeping operation can be easily performed. Such a wideband sweeping operation may be useful for a radar system or the like requiring a wideband chirp signal.

Meanwhile, the unwanted wave cancellation performance may vary depending on the bandwidth of the pass signal of each channel line CL of the manifold coupled multiplexer 3. In order to increase the unwanted rejection performance, first, the frequency of the second harmonic with respect to the minimum frequency of the k + 1 th pass signal is included in the signal pass band of the k th channel line CL _k (hereinafter referred to as “second condition”). May be referred to). In this case, the frequency of the second harmonic relative to the minimum frequency of the k + 1 th pass signal is included between the minimum frequency and the maximum frequency of the k th pass signal.

For example, n is 2 and the case of the minimum frequency F ₃ is 90㎒, second-order harmonic of 2F ₃ (180㎒) of the lowest frequency (F ₃₎ of the second-pass signal of the second signal is passed through the first channel line It must be included in the signal pass band of (CL ₁ ), ie, between the minimum frequency F ₂ and the maximum frequency F ₁ of the first pass signal. In this case, since the second harmonic of F ₃ allows in addition to the signal pass band of the second channel line (CL _2), the second channel line (CL ₂₎ which is the second harmonic of F ₃ effectively removed by the filters connected to the There is an advantage. If, when the second harmonic 2F ₃ (180㎒) of F ₃ is equal to that included in the signal pass band of the second channel line (CL _2), second harmonic wave, the second channel line of F ₃ (CL ₂₎ Filtering is not performed by the filters connected to the overall signal characteristics will deteriorate.

In addition, in order to increase the unnecessary wave removal performance, the signal passing bandwidth BW _k of the _k th channel line CH _k may satisfy the following equation (hereinafter referred to as “third condition”).

(expression)

BW _K = 2F _MIN Ⅹ C _BW

In this case, F _MIN is the minimum frequency of the k th pass signal, and C _BW is a value of less than 1 as a bandwidth adjustment coefficient. That is, the bandwidth adjustment coefficient C _BW is a coefficient value that sets the bandwidth BW _K of the k th pass signal so that the maximum frequency of the k th pass signal is smaller than the second harmonic of the minimum frequency of the k th pass signal.

For example, when n is 2 and the minimum frequency F ₃ of the second pass signal is 90 MHz, the signal pass bandwidth of the second channel line CL ₂ should be designed to be less than ₂ × 90 MHz = 180 MHz. In this case, since the second harmonic of F ₃ allows in addition to the signal pass band of the second channel line (CL _2), the second channel line (CL ₂₎ which is the second harmonic of F ₃ effectively removed by the filters connected to the There is an advantage. If the signal passing bandwidth of the second channel line CL ₂ is 180 MHz or more, the second harmonic of F ₃ is within the signal passing band of the second channel line CL ₂ , and therefore, the second order of F ₃ . Since the harmonics are not filtered by the filters connected to the second channel line CL ₂ , the overall signal characteristics deteriorate.

In order to increase the noise rejection performance and at the same time have the minimum number of channel lines CL, the value of the bandwidth adjustment coefficient C _BW can be a value between 0.6 and 0.9 (hereinafter referred to as “fourth condition”). have. That is, when the value of the bandwidth adjustment coefficient C _BW is smaller than 0.6, the signal passing bandwidth of each channel line CL is too narrow, so that the number of necessary channel lines CL may increase. In addition, when the value of the bandwidth adjustment coefficient C _BW is larger than 0.9, the maximum frequency of the k th pass signal approaches the second harmonic of the minimum frequency of the k th pass signal. In this case, when the characteristics of the filters connected to the _k th channel line CL _k become worse, the second harmonic of the minimum frequency of the k th pass signal may be included in the K th pass signal without being filtered by the corresponding filters. That is, the value of the bandwidth adjustment coefficient (C _BW ) is 0.9 or less as a way to margin the filtering characteristics of each filter.

7 illustrates a frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention further comprising a plurality of frequency multipliers 20 and a mixer 30.

Referring to FIG. 7, the frequency synthesizer using the manifold coupled multiplexer according to an embodiment of the present invention may further include a plurality of frequency multipliers 20 and a mixer 30 in addition to the synthesis unit 10 described above.

A plurality of frequency multipliers 20 are provided, and are sequentially connected to the output of the manifold coupled multiplexer 3 to multiply each signal in turn. At this time, the multiplication ratio of each frequency multiplier 20 may be 2 times, 3 times, etc., and the frequency multiplier 20 having an appropriate multiplication ratio is connected as necessary. In particular, in a broadband use system such as a radar system or the like, a frequency synthesizer having a bandwidth of 1 GHz or more is required (hereinafter referred to as “first requirement”). Therefore, in order to satisfy the first requirement, the frequency multiplier 20 may be provided as many as the final bandwidth is 1 kHz or more.

For example, n is 3, F _{1, which} is the minimum frequency of the entire signal pass band of the manifold coupled multiplexer 3, is 49 MHz, and F ₄ , which is the maximum frequency of the entire signal pass band of the manifold coupled multiplexer 3, is shown. Is 218 MHz, one frequency multiplier 20 _a having _a triple multiplication rate and a frequency multiplier 20 _b having a double multiplication rate are required to satisfy the first requirement.

That is, the total bandwidth BW _T in the combining section 10 is 218 MHz to 49 MHz = 169 MHz. At this time, the bandwidth BW _A multiplied by the first frequency multiplier 20 _a is 507 MHz. Then, the bandwidth BW _B multiplied by the second frequency multiplier 20 _b is 1.014 kHz. Therefore, this way one has a body scale of three times the frequency multiplier (20 _a), and can satisfy the first requirement, if one frequency multiplier is connected in turn (20 _a) having a body magnification of 2x .

The mixer 30 is provided in plural and raises the frequency band of the current signal by using a local signal supplied from the local oscillator 40. In this case, the mixer 30 may be connected between two frequency multipliers 30 or may be connected to a front end or a rear end of the frequency multiplier 30. In particular, in a broadband use system such as a radar system or the like, a frequency synthesizer for outputting a frequency signal in the Ka band band of 26.5 kHz to 40 kHz is required (hereinafter referred to as "second requirement"). Therefore, in order to satisfy the second requirement, the mixer 30 may be provided with as many numbers as the band of the final output signal becomes the Ka band band.

For example, n is 3, F _{1, which} is the minimum frequency of the entire signal pass band of the manifold coupled multiplexer 3, is 49 MHz, and F ₄ , which is the maximum frequency of the entire signal pass band of the manifold coupled multiplexer 3, is shown. Is 218 MHz, in order to satisfy the second requirement, the first mixer 20 _a mixing using a local frequency of 1.2 kHz and the second mixer 20 _b mixing using a local frequency of 13.5 kHz. Are required respectively, and these mixers 20 may be provided at the front or rear ends of the two frequency multipliers 20 described above, respectively, according to the first requirement.

That is, the frequency of the signal output from the combining section 10 is 49MHz to 218MHz. At this time, the frequency of the signal mixed by the first mixer 30 _a using a local frequency of 1.2 kHz is 1.249 kHz to 1.418 kHz. Thereafter, the frequency of the signal multiplied by the first frequency multiplier 20 _a is 3.747 MHz to 4.254 MHz. The frequency of the signal mixed by the second mixer 30 _b using a local frequency of 13.5 kHz is then 17.247 kHz to 17.754 kHz. The frequency of the signal multiplied by the second frequency multiplier 20 _b is then 34.494 kHz to 35.508 kHz. Thus, one frequency multiplier 20 _a having a triple multiplication rate and one frequency multiplier 20 _b having a double multiplication rate and these frequency multipliers 20 _a , 20 _b , 20 _c Even if only two mixers 30 _a and 30 _b are connected to the front end or the rear end of, the second requirement can be satisfied.

That is, the frequency synthesizer using the manifold-coupled multiplexer according to an embodiment of the present invention outputs a wideband signal by connecting a manifold-coupled multiplexer to a conventional direct digital synthesizer module and outputs a wideband signal within the overlap band of each channel. Discontinuities in the phase characteristics of continuous signals can be avoided, which not only improves the broadband frequency characteristics efficiently but also reduces the number of additionally connected frequency multipliers and mixers to a minimum, thereby reducing signal loss and unwanted waves. Level and phase noise degradation can be minimized and manufacturing costs can be reduced.

The local oscillator 40 is connected to the mixer 30 and supplies a local signal, but may be implemented as a phase-locked voltage controlled oscillator (PLVCO), but is not limited thereto.

Frequency synthesizer using a manifold coupled multiplexer according to an embodiment of the present invention, in addition to Ka band band, C band band, X band band, Ku band band, K band band, V band band, W band band, M band band, etc. Can also generate a frequency signal. At this time, according to the frequency band to be generated, the output band of the digital synthesizer module 2, the number of the frequency multiplier 20 and the mixer 30, the multiplication ratio of each frequency multiplier 20, and each mixer 30 The frequency of the local signal used in the) may be adjusted.

On the other hand, in a broadband use system such as a radar system or the like, a high speed system having a DC-AC converting time resolution (DAC Time Resolutions) of 5 ms or less requires (hereinafter referred to as “third requirement”). In order to satisfy this third requirement, the direct digital synthesizer module 2 having the corresponding DC-AC converting time resolution may be selected. For example, ADI's AD9910 has a DC-to-AC conversion time resolution of about 4.4 ㎱, which can satisfy the third requirement when implementing the digital synthesizer module 2 directly with the AD9910.

In the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined by the following claims and their equivalents.

1: reference signal generator 2: direct digital synthesizer module
3: manifold coupled multiplexer 10: synthesis section
20: multiplier 30: mixer
40: local oscillator BW: bandwidth
CL: Channel line CLK _R : Reference signal
CN: Join Node DN: Distribution Node
DAC: DC-to-AC Converter F _CW : Frequency Information
HPF: High Pass Filter LPF: Low Pass Filter
PA: Phase Accumulator PSC: Phase-Sine Converter

Claims (10)

A direct frequency synthesizer module for outputting a signal within a specific frequency band; And
Directly divides the signal output from the frequency synthesizer module into n channel lines (where n is a natural number of 2 or more), and includes a plurality of filters for filtering the signals of each channel line into different bands. And a manifold coupled multiplexer having a rear end of each channel line coupled to multiplex the output signal. The method of claim 1,
The signal passband of each channel line implemented by one or more filters connected to each channel line is different from each other, and k is the minimum of the kth pass signal passing through the kth channel line (where k is a natural number between 1 and n-1). And a frequency equal to a maximum frequency of a k + 1 th signal passing through a k + 1 th channel line. The method of claim 2,
And a frequency of the second harmonic with respect to the minimum frequency of the k + 1 th pass signal is included in the signal pass band of the k th channel line. The method of claim 2,
And a signal passing bandwidth B _{k k} of the k-th channel line satisfies the following equation.
(expression)
BW _K = 2F _MIN Ⅹ C _BW
(F _MIN is the minimum frequency of the k th pass signal, C _BW is the bandwidth adjustment factor, a value less than 1) The method of claim 1,
The manifold coupled multiplexer when n is 2,
A first upper low pass filter having a signal output from the direct frequency synthesizer module into one end, the other end connected to the first branch node, and having a high cutoff frequency of F ₁ MHz;
A first top high pass filter having one end connected to the first branch node and having a low cutoff frequency of F ₂ MHz;
A first lower high pass filter, one end of which is connected to the other end of the first upper high pass filter, the other end of which is connected to the first coupling node, and whose low cutoff frequency is F ₂ MHz;
A first lower low pass filter having one end connected to the first coupling node, the multiplexed output signal being output to the other end, and having a high cutoff frequency of F ₁ MHz;
A second upper low pass filter, one end of which is connected to the first branch node, wherein the high pass cutoff frequency is F ₂ MHz;
A second upper high pass filter having one end connected to the other end of the second upper low pass filter and having a low cutoff frequency of F ₃ MHz;
A second lower high pass filter having one end connected to the other end of the second upper high pass filter and having a low cutoff frequency of F ₃ MHz; And
A second lower low pass filter having one end connected to the other end of the second lower high pass filter, the other end connected to the first coupling node, and having a high cutoff frequency of F ₂ MHz; Broadband high-frequency synthesizer The method of claim 1,
The manifold coupled multiplexer when n is 3 or more,
A first upper low pass filter having a signal output from the direct frequency synthesizer module into one end, the other end connected to the first branch node, and having a high cutoff frequency of F ₁ MHz;
A first top high pass filter having one end connected to the first branch node and having a low cutoff frequency of F ₂ MHz;
A first lower high pass filter, one end of which is connected to the other end of the first upper high pass filter, the other end of which is connected to the first coupling node, and whose low cutoff frequency is F ₂ MHz;
A first lower low pass filter having one end connected to the first coupling node, the multiplexed output signal being output to the other end, and having a high cutoff frequency of F ₁ MHz;
A j-th top low pass filter, one end of which is connected to the j-th branch node (where j is 2 to n-1), the other end of which is connected to the j-th branch node, and having a high frequency cutoff frequency of F _j MHz;
A j-th top high pass filter, _one end of which is connected to a j-th branch node and has a low cut-off frequency of F _{j + 1} MHz;
A j th lower high pass filter, one end of which is connected to the other end of the j th top high pass filter, the other end of which is connected to the j th coupling node, and wherein the low pass cutoff frequency is F _{j + 1} MHz;
A j-th low pass filter having one end connected to the j th coupling node, the other end connected to the j-1 coupling node, and having a high cutoff frequency of F _j MHz;
An n-th top low pass filter, one end of which is connected to the n-th branch node and having a high cut-off frequency of F _n MHz;
An nth top high pass filter having _one end connected to the other end of the nth top low pass filter and having a low cutoff frequency of F _{n + 1} MHz;
An n th lower high pass filter, _one end of which is connected to the other end of the n th upper high pass filter, and having a low cutoff frequency of F _{n + 1} MHz; And
A second lower low pass filter having one end connected to the other end of the n th lower high pass filter, the other end connected to the n-1 coupling node, and having a high cutoff frequency of F _n MHz; Broadband Fast Frequency Synthesizer using Combined Multiplexer. The method according to claim 5 or 6,
A wideband fast frequency synthesizer using a manifold coupled multiplexer characterized in that the magnitude of the frequencies decreases in the order of F ₁ to F _{n + 1} . The method of claim 1,
A plurality of frequency multipliers sequentially connected to the output of the manifold coupled multiplexer; And
And at least one mixer connected to a front end or a rear end of the frequency multiplier and configured to raise a frequency band of a signal. The method of claim 8,
And a bandwidth of the final output signal multiplied by the plurality of frequency multipliers is 1 kHz or more. The method of claim 8,
The frequency band of the final output signal raised through the mixer and the plurality of frequency multipliers is C band band, X band band, Ka band band, Ku band band, K band band, V band band, W band band and M band band. Broadband high-speed frequency synthesizer using a manifold coupled multiplexer, characterized in that any one of.

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