KR102477864B1 - A frequency hopping spread spectrum frequency synthesizer - Google Patents

Abstract

The present invention discloses a frequency hopping spread spectrum frequency synthesizer. The device includes a divider chain that receives a complex signal from a complex phase-locked loop and outputs a divided complex signal by adjusting a division ratio in response to a band selection signal; a single-sideband calculator for receiving the complex signal and the frequency-divided complex signal, adding and subtracting frequencies, and outputting the added and subtracted frequencies; and an injection-locked oscillator for performing frequency hopping by converting a capacitance value having the added and subtracted frequency as a resonance frequency into a digital code and performing filtering. It is characterized in that it includes. According to the present invention, spurs generated in a frequency synthesizer having a frequency hopping capability of a phase-locked loop can be significantly reduced, so that an autonomous driving device equipped with a radar system using frequency hopping can be efficiently configured. there will be

Description

A frequency hopping spread spectrum frequency synthesizer}

The present invention relates to a frequency synthesizer, and more particularly, an injection-locked oscillator performs a filter function to reduce a spur generated when a phase-locked loop frequency hops, thereby minimizing a frequency hop time in an autonomous driving system. It relates to a hopping spread spectrum frequency synthesizer.

In general, a phase-locked loop (PLL) circuit refers to a circuit that controls an output signal using a phase difference between an input signal and a signal fed back from an output signal.

In adjusting the frequency of the output signal according to the input signal, a phase difference between the result of the frequency divider of the current output signal, which is a feedback loop, and the input signal is detected.

Then, the detected phase difference is determined as an error, and the output frequency is adjusted to be changed by adjusting the input voltage of the voltage controlled oscillator (VCO) to reduce the error.

When the feedback phase difference between the input and output is synchronized, the phase is locked, and the frequency of the output to the input is adjusted so that the locked state is maintained.

A phase locking circuit for processing a radio signal means a phase locking device used in a radio circuit, and refers to a phase locking loop circuit for synchronizing the phase of a transmitted signal.

Phase synchronization refers to controlling a frequency oscillator or periodic signal generator to operate at a constant phase angle with respect to a reference signal source.

Accordingly, the phase-locked loop is used for synchronous demodulation of digital modulated waves, tracking of coherent carriers, extension of thresholds, synchronization of bits, synchronization of symbols, and the like.

Meanwhile, as autonomous driving has recently been in the limelight, demand for a radar, which is an essential sensor device for autonomous driving, is increasing.

A widely used frequency modulation method for existing radars is a method using a frequency modulated continuous wave (FMCW), which has a disadvantage of being vulnerable in an environment with various obstacles.

1 is a schematic circuit diagram of a radar receiving end according to the prior art.

FIG. 2 is a graph showing a interference signal versus a transmission/reception signal of a frequency modulated continuous wave according to a frequency modulation method in the radar receiver shown in FIG. 1 .

3 is a graph showing the loss of data according to the magnitude of the interference signal in the video graphics array (VGA) in the radar receiver shown in FIG. 1, (a) is the intensity of the video graphics array input signals, (b) is the intensity of the image graphic array output signals.

FIG. 4 shows the intensity (b) of input signals versus the intensity (c) of output signals of a transmission/reception signal (a) of a frequency modulated continuous wave according to a method for transmitting and receiving a signal using spread spectrum in the radar receiver shown in FIG. 1; it's a graph

In FIG. 1, a frequency modulated continuous wave transmission/reception signal and a jamming signal can be seen. As shown in FIG. There was a problem with loss.

Moreover, in a situation such as autonomous driving in which a plurality of radars transmit and receive similar signals, radars of a plurality of vehicles generate similar signals and become signals that interfere with each other.

However, the narrowband signal processing method of the frequency modulated continuous wave at the receiving end has a disadvantage in that it is vulnerable to such an interfering signal.

In addition, transmission and reception of signals using a spread spectrum have characteristics that are robust against interference signals, unlike frequency-modulated continuous waves. Representatively, the frequency hopping spread spectrum (FHSS) shown in FIG. There is a signal transmission and reception method using orthogonal frequency division multiplexing (OFDM).

In particular, orthogonal frequency division multiplexing using frequency hopping to digest a wide bandwidth in a high frequency band can simultaneously perform communication and radar functions.

The above-mentioned frequency hopping spread spectrum robust against interference signals or the orthogonal frequency division multiplexing method using frequency hopping require a frequency synthesizer having frequency hopping capability.

In addition, the time taken for frequency hopping is an important factor in determining the performance of a radar system and provides flexibility in system configuration.

However, conventional frequency synthesizers having frequency hopping capability have chronic problems such as generation of spurs, which makes it difficult to configure a radar system using frequency hopping.

That is, if the phase-locked loop replaces the analog circuit part with a digital circuit in order to reduce analog characteristics that are sensitive to process, voltage, and temperature changes, the effect of noise caused by the analog characteristics is reduced, but quantization occurs due to the limited resolution of the system. It is greatly affected by noise.

This quantization noise increases the phase noise of the output signal of the all-digital phase-locked loop and forms a periodic pattern to generate spurs, which is a major obstacle to radar devices, which are essential sensor devices for autonomous driving systems. can act as

On the other hand, conventional frequency synthesizer structures with frequency hopping capability include a structure based on a two-point modulation method, a frequency multiplication structure using an injection locked oscillator (ILO), and a single side wave band mixer. There is a structure based on (Single-sideband Mixer).

First, the two-point modulation method obtains a desired modulated signal at the output end by simultaneously applying a step-modulated signal to a path having a low-pass characteristic of a phase-locked loop and a path having a high-pass band characteristic to obtain a frequency hopping output. to be.

In this case, when there is an error in the gains of the low-pass path and the high-pass path, the hopping time increases.

Therefore, in order to reduce the gain error of the two paths, a complicated circuit must be constructed. According to statistical data published in the art, a method for obtaining a leap time of about 100 ns has been known.

Second, the frequency multiplication method using an injection-locked oscillator is a method in which multiple frequencies of a reference frequency are extracted, and then the injection-locked oscillator is matched to one of these multiple frequencies.

This method instantaneously changes the capacitance of an injection-locked oscillator for frequency hopping to match a different multiple frequency, and the hopping time announced in the art is known to be within 3 ns.

In addition, spurs caused by the reference frequency will appear on the output. If a lower reference frequency is used, the spurs will be generated close to the signal, making it difficult for the injection-locked oscillator to match the desired multiple frequency, and leaving a stronger spur. There is a downside to being

Moreover, since the harmonic extraction part extracts several adjacent multiple frequencies with the same gain, spurs generated by multiple frequencies close to the desired frequency may cause a big problem.

For example, when the desired frequency is a 13th multiple frequency, adjacent 11th to 15th frequencies are also extracted with the same gain.

Therefore, this method inevitably has a limitation in that a high reference frequency must be used, which limits the frequency design of the entire system.

Third, the frequency hopping structure based on a single-sideband (SSB) mixer is a method of obtaining a frequency addition or subtraction result by using a single-sideband mixer with fixed frequency generators.

This method consumes a frequency hopping time equivalent to a switching time for changing a combination of desired frequencies, and the hopping time announced in the art is known to be within 1 ns.

However, the input of the mixer requires a complex signal of each of two frequencies, and when a complex signal error exists, the spur problem in the output becomes more serious.

In general, frequency hopping spread spectrum requires a SideBand Rejection Ratio (SBRR), which is a measure of attenuation of image frequencies above 36 dB.

For example, if a complex signal has an amplitude error of 0.2 dB, a phase error of about 1 degree is required to obtain a sideband rejection ratio of 36 dB or more.

However, this degree of phase error is a very difficult value to achieve, and considering that radar applications are usually made in the high mm-wave band, it is even more difficult to achieve the error of a complex signal as the intended value. Its use for frequency hopping was limited and limited.

Korean Patent Publication KR 10-2006-0090909 A

An object of the present invention is to make an injection-locked oscillator in a frequency synthesizer of a phase-locked loop perform a filter function of the output of a single-side wave band operator, so that even in an environment with obstacles or an autonomous navigation system in which a plurality of radars operate, loss of data or loss of signals An object of the present invention is to provide a frequency hopping spread spectrum frequency synthesizer capable of minimizing a frequency hopping time without interference.

The object of the present invention is not limited to the above-mentioned object, and other objects and advantages of the present invention not mentioned above can be understood by the following description and will be more clearly understood by the examples of the present invention. It will also be readily apparent that the objects and advantages of the present invention may be realized by means of the instrumentalities and combinations thereof set forth in the claims.

A frequency hopping spread spectrum frequency synthesizer of the present invention for achieving the above object includes a divider chain receiving a complex signal from a complex phase-locked loop, adjusting a division ratio in response to a band selection signal, and outputting a divided complex signal; a single-sideband calculator for receiving the complex signal and the frequency-divided complex signal, adding and subtracting frequencies, and outputting the added and subtracted frequencies; and an injection-locked oscillator for performing frequency hopping by converting a capacitance value having the added and subtracted frequency as a resonance frequency into a digital code and performing filtering. It is characterized in that it includes.

A frequency hopping spread spectrum frequency synthesizer of the present invention for achieving the above object includes a control unit outputting the band selection signal, the first direction signal and the second direction signal; It is characterized in that it further comprises.

The frequency hopping spread spectrum frequency synthesizer of the present invention for achieving the above object is characterized in that the complex phase-locked loop is a fractional ratio-N phase-locked loop and is a complex voltage controlled oscillator that generates the complex signal.

In order to achieve the above object, in the frequency hopping spread spectrum frequency synthesizer of the present invention, the complex voltage controlled oscillator is in the form of a differential amplifier, one side of each of a plurality of pairs of MOS transistors is connected in parallel to a current source, and the other side converts the complex signal to a phase of 90 degrees. It is characterized in that it outputs sequentially with a difference.

In order to achieve the above object, in the frequency hopping spread spectrum frequency synthesizer of the present invention, the complex voltage controlled oscillator sequentially converts the complex signal with a phase difference of 90 degrees using an annular series connection of a plurality of diode-connected MOS transistors. It is characterized by output.

The frequency hopping spread spectrum frequency synthesizer of the present invention for achieving the above object is characterized in that the divider chain is a current mode logic frequency divider.

In order to achieve the above object, in the frequency hopping spread spectrum frequency synthesizer of the present invention, the divider chain outputs a plurality of pairs of signals for adjusting the order of the complex signals in response to the first direction signal and the second direction signal. first to fourth multiplexers; It is characterized in that it includes.

In order to achieve the above object, in the frequency hopping spread spectrum frequency synthesizer of the present invention, the divider chain receives a positive first signal and a negative first signal, and when the value of the first direction signal is (+), a positive value is generated. a first multiplexer outputting a first signal and outputting a negative first signal when the value of the first direction signal is (-); When a positive first signal and a negative first signal are input, a negative first signal is output when the value of the first direction signal is (+), and a positive first signal is output when the value of the first direction signal is (-). a second multiplexer to which the first signal of is output; When a positive second signal and a negative second signal are input, a negative second signal is output when the value of the second direction signal is (+), and a positive second signal is output when the value of the second direction signal is (-). a third multiplexer to which the second signal of is output; and when a positive second signal and a negative second signal are input and the value of the second direction signal is (+), a positive second signal is output, and when the value of the second direction signal is (-) a fourth multiplexer outputting a negative second signal; It is characterized in that it includes.

In order to achieve the above object, the frequency hopping spread spectrum frequency synthesizer of the present invention includes a current source connected to the ground in the injection-locked oscillator; a first pair of MOS transistors, one side of which is connected in parallel to the current source, and receives a (+) injection signal or (-) injection signal to each gate terminal; a second pair of MOS transistors having one side connected to the other side of the first pair of MOS transistors and outputting a (+) output voltage signal or a (-) output voltage signal from the other side; and a resonator having one side connected to the other side of the second pair of MOS transistors and the other side connected to a power supply voltage to generate a resonance phenomenon. It is characterized in that it includes.

In order to achieve the above object, a frequency hopping spread spectrum frequency synthesizer of the present invention includes a load inductor to which the power supply voltage is connected to a central portion of the resonator unit; and a variable capacitor connected in parallel to the other side of the second pair of MOS transistors and the load inductor to convert the capacitance value into a variable digital code through the resonance phenomenon at the resonance frequency. It is characterized in that it includes.

In the frequency hopping spread spectrum frequency synthesizer of the present invention to achieve the above object, the injection-locked oscillator adjusts the value of the variable capacitor with a temperature difference measuring code and converts the variable digital code into the variable digital code.

Details of other embodiments are included in "Specific Contents for Carrying Out the Invention" and the accompanying "Drawings".

Advantages and/or features of the present invention, and methods of achieving them, will become apparent upon reference to the various embodiments described below in detail in conjunction with the accompanying drawings.

However, the present invention is not limited only to the configuration of each embodiment disclosed below, but may also be implemented in various other forms, and each embodiment disclosed herein only makes the disclosure of the present invention complete, and this It is provided to completely inform the scope of the present invention to those skilled in the art to which the invention belongs, and it should be noted that the present invention is only defined by the scope of each claim of the claims.

According to the present invention, spurs generated in a frequency synthesizer having a frequency hopping capability of a phase-locked loop can be significantly reduced, so that an autonomous driving device equipped with a radar system using frequency hopping can be efficiently configured. there will be

In addition, since the order of complex signals input to the frequency synthesizer of the present invention is accurately defined, frequency addition and subtraction operations in the single-sideband calculator can be accurately implemented.

In addition, while using the injection-locked oscillator as a filter, the settling time that is unavoidably additionally required is reduced, so that the operation of the frequency synthesizer is rapidly stabilized in the frequency band.

1 is a schematic circuit diagram of a radar receiving end according to the prior art.
FIG. 2 is a graph showing a interference signal versus a transmission/reception signal of a frequency modulated continuous wave according to a frequency modulation method in the radar receiver shown in FIG. 1 .
FIG. 3 is a graph showing data loss according to the magnitude of an interference signal in a video graphics array (VGA) in the radar receiver shown in FIG. 1;
FIG. 4 shows the intensity (b) of input signals versus the intensity (c) of output signals of a transmission/reception signal (a) of a frequency modulated continuous wave according to a method for transmitting and receiving a signal using spread spectrum in the radar receiver shown in FIG. 1; it's a graph
5 is a block diagram of a frequency hopping spread spectrum frequency synthesizer according to one embodiment of the present invention.
FIG. 6 is a simulation result of the stabilization time of the frequency synthesizer shown in FIG. 5, a change in the frequency of the injection-locked oscillator 150 over time (a) and a change in the output voltage of the injection-locked oscillator 150 (b) it's a graph
FIG. 7 is a graph of spectrum simulation results using the frequency synthesizer shown in FIG. 5 .
8 and 9 are examples of circuit diagrams of the complex voltage controlled oscillator constituting the complex phase locked loop 120 in the frequency synthesizer shown in FIG. 5 .
FIG. 10 is a circuit diagram of a divider chain 130 in the frequency synthesizer shown in FIG. 5 .
FIG. 11 is a circuit diagram of an injection-locked oscillator 150 in the frequency synthesizer shown in FIG.
FIG. 12 is a graph of a change in the output frequency of the injection-locked oscillator 150 versus time as a result of simulation of the frequency synthesizer shown in FIG. 5 .

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

Before describing the present invention in detail, the terms or words used in this specification should not be construed unconditionally in a conventional or dictionary sense, and in order for the inventor of the present invention to explain his/her invention in the best way Concepts of various terms can be appropriately defined and used.

Furthermore, it should be noted that these terms or words should be interpreted as meanings and concepts consistent with the technical idea of the present invention.

That is, the terms used in this specification are only used to describe preferred embodiments of the present invention, and are not intended to specifically limit the contents of the present invention.

It should be noted that these terms are terms defined in consideration of various possibilities of the present invention.

Also, in this specification, a singular expression may include a plurality of expressions unless the context clearly indicates otherwise.

In addition, it should be noted that similarly, even if expressed in a plurality, it may include a singular meaning.

Throughout this specification, when a component is described as "including" another component, it does not exclude any other component, but further includes any other component, unless otherwise stated. It can mean you can do it.

Furthermore, when a component is described as "existing inside or connected to and installed" of another component, this component may be directly connected to or installed in contact with the other component.

In addition, it may be installed at a certain distance, and in the case of being installed at a certain distance, a third component or means for fixing or connecting the corresponding component to another component may exist. .

Meanwhile, it should be noted that the description of the third component or means may be omitted.

On the other hand, when it is described that a certain element is "directly connected" to another element, or is "directly connected", it should be understood that no third element or means exists.

Similarly, other expressions describing the relationship between components, such as "between" and "directly between", or "adjacent to" and "directly adjacent to" have the same meaning. should be interpreted as

In addition, in the present specification, terms such as "one side", "the other side", "one side", "the other side", "first", and "second" refer to one component with respect to another component. It is used to make it clearly distinguishable from the elements.

However, it should be noted that the meaning of a corresponding component is not limitedly used by such a term.

In addition, in this specification, terms related to positions such as “upper”, “lower”, “left”, “right”, etc., if used, are to be understood as indicating relative positions of corresponding components in the drawing.

In addition, unless an absolute location is specified for these locations, these location-related terms should not be understood as referring to an absolute location.

Moreover, in the specification of the present invention, terms such as "... unit", "... unit", "module", and "device", if used, mean a unit capable of processing one or more functions or operations.

It should be noted that this may be implemented in hardware or software, or a combination of hardware and software.

In the drawings accompanying this specification, the size, position, coupling relationship, etc. of each component constituting the present invention is partially exaggerated, reduced, or omitted in order to sufficiently clearly convey the spirit of the present invention or for convenience of explanation. may be described, and therefore the proportions or scale may not be exact.

In addition, in the following description of the present invention, a detailed description of a configuration that is determined to unnecessarily obscure the subject matter of the present invention, for example, a known technology including the prior art, may be omitted.

5 is a block diagram of a frequency hopping spread spectrum frequency synthesizer according to an embodiment of the present invention, comprising a controller 110, a complex phase locked loop 120, a divider chain 130, a single side wave band operator 140, and and an injection locked oscillator (150).

Referring to FIG. 5, the function of each component of the frequency hopping spread spectrum frequency synthesizer according to an embodiment of the present invention is schematically described as follows.

The controller 110 outputs a band selection signal (Band Selection), a first direction signal (I direction), and a second direction signal (Q direction).

The divider chain 130 receives the complex signal w ₁ from the complex phase locked loop 120, adjusts the division ratio in response to a band selection signal, and outputs the divided complex signal w ₂ . .

The single-sideband operator 140 receives the complex signal w ₁ and the complex signal w ₂ divided by the divider chain 130, adds and subtracts frequencies, and outputs the result.

The injection-locked oscillator 150 performs frequency hopping by converting the capacitance value whose resonant frequency is the frequency added and subtracted by the single side wave band operator 140 into a digital code and filtering it.

FIG. 6 is a graph of the change in the injection-locked oscillator frequency versus time as a result of simulation of the stabilization time of the frequency synthesizer shown in FIG. 5 (a) and a graph of the change in output voltage of the injection-locked oscillator 150 (b) )to be.

FIG. 7 is a graph of spectrum simulation results using the frequency synthesizer shown in FIG. 5 .

The operation of the frequency hopping spread spectrum frequency synthesizer according to an embodiment of the present invention will be described in detail with reference to FIGS. 5 to 7 .

The divider chain 130 receives the complex signal w ₁ from the complex phase-locked loop (Quad LO) 120 and generates a band selection signal, a first direction signal, that is, an I direction signal (I direction) and a second direction signal (I direction). In response to a two-way signal, that is, a Q direction signal (Q direction), the divided complex signal (w ₂ ) is changed and output by adjusting a division ratio.

At this time, the band selection signal (Band Selection), the I direction signal (I direction), and the Q direction signal (Q direction) are control signals output from the controller 110 such as a microprocessor.

In addition, the band selection signal (Band Selection) is set to 9 bits when the resolution is low (coarse), and is set to 12 bits when the resolution is high (fine).

The single-sideband calculator 140 receives the complex signal w ₁ of the complex phase locked loop 120 and the complex signal w ₂ divided by the divider chain 130, and adds and subtracts frequencies.

The injection-locked oscillator 150 converts a capacitance value having a frequency of w ₁ +w ₂ or w ₁ -w ₂ , which is a frequency added or subtracted by the single-side wave band operator 140 as a resonance frequency, into a digital code, and selects a band. Frequency hopping is executed by adjusting the capacitance array with the converted digital code in response to the signal (Band Selection).

Meanwhile, the stabilization time generated while additionally using the injection-locked oscillator 150 takes the reciprocal of the locking range of the injection-locked oscillator 150 as a time constant τ.

At this time, when the injection lock oscillator 150 has a lock range of 500 MHz, a stabilization time of about 2 ns can be theoretically obtained. As a result of simulation of the actual stabilization time, FIGS. ), it can be seen that similar results are obtained.

That is, when the frequency of the injection-locked oscillator 150 in FIG. 6 (a) is changed from 64 GHz to 56 GHz, as a result of simulation of the stabilization time of the frequency synthesizer of the present invention shown in FIG. 150) is changed as shown in the graph of FIG. 6(b) for about 0.7 ns.

Therefore, when the injection-locked oscillator 150 of the present invention is applied to a frequency oscillator of a radar system using a frequency band in the mm-wave region, immediate frequency hopping is possible.

The complex signal (w ₁ ) output from the complex phase locked loop 120 of FIG. 5 is 60 GHz, and the complex signal (w ₂ ) divided by the frequency divider chain 130 is set to have a frequency of 2 GHz, An operation of adding both signals in the single side wave band calculator 140 was simulated.

In FIG. 7 , a solid yellow line is an output signal of the single-sideband calculator 140, and it can be seen that the spur is strong, and a blue dotted line is a signal that has passed through the injection-locked oscillator 150, and it can be seen that the spur is reduced.

The red solid line is a signal normalized by the intensity of the output signal of the short side wave band operator 140 for comparison between both signals, and it can be seen that the side wave band exclusion ratio value is about 56 dB.

In general, a sideband band exclusion ratio value of 36 dB or more is required for frequency hopping spread spectrum, and the spectrum simulation results using the frequency synthesizer of the present invention not only fully satisfy this condition, but also This corresponds to a level that significantly exceeds the value of the sideband exclusion ratio of

8 and 9 are examples of circuit diagrams of the complex voltage controlled oscillator constituting the complex phase locked loop 120 in the frequency synthesizer shown in FIG. 5 .

FIG. 10 is a circuit diagram of the divider chain 130 in the frequency synthesizer shown in FIG. 5, and includes first to fourth multiplexers MUX1 to MUX4.

11 is a circuit diagram of an injection-locked oscillator 150 in the frequency synthesizer shown in FIG. 5, including a current source 151, first and second pairs of MOS transistors 152 and 153, and a resonator 154; The resonator 154 includes a load inductor (L) and a variable capacitor (C _var ).

FIG. 12 is a graph of a change in the output frequency of the injection-locked oscillator 150 versus time as a result of simulation of the frequency synthesizer shown in FIG. 5 .

As shown in FIGS. 8 and 9, the complex phase-locked loop 120 in the frequency synthesizer of the present invention is a complex voltage controlled oscillator and is composed of a fractional-N phase-locked loop to generate a complex signal. do.

The phase-locked loop adjusts the frequency of the output signal according to the input signal, and detects the phase difference between the frequency divider result of the current output signal and the input signal, which is a feedback loop.

At this time, the frequency difference between the input signal and the output signal of the phase-locked loop ultimately depends on the frequency divider N.

That is, according to a multiple of N, the frequency of the output signal becomes N times the frequency of the input signal.

The fractional ratio-N phase-locked loop of the present invention, as shown in FIG. 8 so that the order of complex signals is clear, in the form of a differential amplifier, for example, two pairs of MOS transistors (M ₁ and M ₂ , M ₃ and M ₄ ) are each connected in parallel to the current source 151 to sequentially obtain an output having a phase difference of 90 degrees.

In addition, as shown in FIG. 9, output having a phase difference of 90 degrees may be sequentially obtained by using a plurality of diode-connected, for example, four MOS transistors M _C1 to M _C4 connected in an annular series.

Meanwhile, the divider chain 130 in the frequency synthesizer of the present invention is a Current Mode Logic (CML) frequency divider, and due to the characteristics of the current mode logic frequency divider, a complex signal having a clear sequence can be obtained. .

That is, a plurality of pairs of output signals that are outputs of the divider chain 130, for example, a positive first signal (I+) and a negative first signal (I-) and a positive second signal (Q+) and a negative As shown in FIG. 10, the first signal Q- of is a complex signal in response to the I direction signal I DIRECTION and the Q direction signal Q DIRECTION using the first to fourth multiplexers MUX1 to MUX4. You can adjust the order of

In other words, when the value of the I direction signal I DIRECTION is (+), the I+ signal is output from the first multiplexer MUX1 and the I- signal is output from the second multiplexer MUX2.

Also, when the value of the I direction signal I DIRECTION is (-), an I- signal is output from the first multiplexer MUX1 and an I+ signal is output from the second multiplexer MUX2.

On the other hand, when the value of the Q direction signal Q DIRECTION is (+), the Q− signal is output from the third multiplexer MUX3 and the Q+ signal is output from the fourth multiplexer MUX4.

Also, when the value of the Q direction signal Q DIRECTION is (-), the Q+ signal is output from the third multiplexer MUX3 and the Q- signal is output from the fourth multiplexer MUX4.

Through this, the frequency synthesizer of the present invention can accurately implement frequency addition and subtraction operations in the single-sideband operator 140 by accurately defining the order of complex signals in the divider chain 130.

In addition, the injection-locked oscillator ₁₅₀ in the frequency synthesizer of the present invention is implemented as a differential amplifier structure as shown in FIG. (Q factor) is guaranteed.

Here, the term 'variable code by step' means that whenever the size of the code increases or decreases step by step, the size of the action (in the present invention, the size of the capacitance value) also increases or decreases step by step in proportion thereto.

In addition, the meaning of 'guarantee of performance factors' is as follows.

In general, in a frequency oscillator system in a high frequency band, one of the factors impeding the frequency oscillator performance factor is a parasitic component. In particular, when a variable capacitor is used as a capacitor with a large capacitance, the parasitic component increases in proportion to this. .

Therefore, in the present invention, it means that the parasitic component of the frequency oscillator is minimized by using a variable capacitance of the smallest possible unit as a step-by-step variable code.

Meanwhile, in FIG. 11 , when the first pair of MOS transistors 152 are turned on by receiving the (+) injection signal (INJ+) and the (-) injection signal (INJ-) to their gate terminals, respectively, the current of the current source 151 passes through the first pair of MOS transistors 152, and through the drain terminals of the second pair of MOS transistors 153, a (+) output voltage signal (OUT+) and a (-) output voltage signal (OUT-) are output do.

At this time, the reason why each pair of MOS transistors are cross-coupled is to prevent an oscillation stop phenomenon due to a leakage current in the injection-locked oscillator 150 in the frequency synthesizer according to the prior art through a (+) feedback operation.

In addition, the frequencies according to the capacitance code of the injection-locked oscillator 150 due to the resonance phenomenon of the load inductor L and the variable capacitor C _var can be obtained as shown in FIG. 12, and a 9-bit coarse bit ) and a 12-bit fine bit band selection signal (Band Selection).

At this time, as the capacitance code is increased, the injection-locked oscillator 150 oscillates at a lower frequency.

As shown in FIG. 12, the simulated frequency of the injection-locked oscillator 150 in the frequency synthesizer of the present invention ranges from about 54.5 GHz to 67.3 GHz for about 0.26 ns, enabling frequency hopping between frequencies suitable for the capacitance code. do.

Therefore, the present invention operates as a frequency synthesizer with high performance as well as the requirement of 'spur reduction' required for application of frequency hopping, which was difficult to achieve in the prior art.

In addition, while using the injection-locked oscillator 150 as a filter, the settling time that is unavoidably additionally required is inversely proportional to the lock range of the injection-locked oscillator 150, and as the operating frequency of the injection-locked oscillator 150 increases, Since the locking range of the injection-locked oscillator 150 also increases, the faster the settling time is obtained as the injection-locked oscillator 150 operates at a higher frequency.

Accordingly, in view of the trend of current frequency oscillator technology that gradually uses higher frequencies, the method of using the injection-locked oscillator 150 as a filter is promising.

Although the MOS transistors in the complex phase-locked loop 120 and the injection-locked oscillator 150 are exemplified and described as NMOS MOS transistors, this is not limiting this as an example, and a PMOS MOS transistor may be used. .

In this way, the present invention makes the injection-locked oscillator in the frequency synthesizer of the phase-locked loop perform the filter function of the single-sideband calculator output, so that even in an environment with obstacles or an autonomous navigation system in which a plurality of radars operate, data loss or signal loss A frequency hopping spread spectrum frequency synthesizer capable of minimizing a frequency hopping time without interference is provided.

Through this, the present invention significantly reduces spurs generated in a frequency synthesizer having a frequency hopping capability of a phase locked loop, so that an autonomous driving device equipped with a radar system using frequency hopping can be efficiently configured. do.

In addition, since the order of complex signals input to the frequency synthesizer of the present invention is accurately defined, frequency addition and subtraction operations in the single-sideband calculator can be accurately implemented.

In addition, while using the injection-locked oscillator as a filter, the settling time that is unavoidably additionally required is reduced, so that the operation of the frequency synthesizer is rapidly stabilized in the frequency band.

In the above, several preferred embodiments of the present invention have been described with some examples, but the description of various embodiments described in the "Specific Contents for Carrying Out the Invention" section is only exemplary, and the present invention Those skilled in the art will understand from the above description that the present invention can be practiced with various modifications or equivalent implementations of the present invention can be performed.

In addition, since the present invention can be implemented in various other forms, the present invention is not limited by the above description, and the above description is intended to complete the disclosure of the present invention and is common in the technical field to which the present invention belongs. It is only provided to fully inform those skilled in the art of the scope of the present invention, and it should be noted that the present invention is only defined by each claim of the claims.

110: control unit
120: complex phase locked loop
130: divider chain
140: single side wave band calculator
150: injection lock oscillator

Claims (11)

a divider chain that receives a complex signal from the complex phase-locked loop, adjusts a division ratio in response to a band selection signal, and outputs a divided complex signal;
a single-sideband calculator for receiving the complex signal and the frequency-divided complex signal, adding and subtracting frequencies, and outputting the added and subtracted frequencies; and
an injection-locked oscillator that performs frequency hopping by converting a capacitance value having the added and subtracted frequency as a resonance frequency into a digital code and performing filtering;
Characterized in that it includes,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 1,
a control unit outputting the band selection signal, first direction signal, and second direction signal;
Characterized in that it further comprises,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 1,
The complex phase locked loop is
A fractional ratio-N phase-locked loop, characterized in that it is a complex voltage controlled oscillator that generates the complex signal,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 3,
The complex voltage controlled oscillator is
In the form of a differential amplifier, one side of each of a plurality of pairs of MOS transistors is connected in parallel to a current source, and the complex signal is sequentially output with a phase difference of 90 degrees from the other side.
Frequency hopping spread spectrum frequency synthesizer.
According to claim 3,
The complex voltage controlled oscillator is
Characterized in that the complex signal is sequentially outputted with a phase difference of 90 degrees using an annular series connection of a plurality of diode-connected MOS transistors.
Frequency hopping spread spectrum frequency synthesizer.
According to claim 1,
The divider chain is
Characterized in that it is a current mode logic frequency divider,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 2,
The divider chain is
first to fourth multiplexers outputting a plurality of pairs of signals for adjusting the order of the complex signals in response to the first direction signal and the second direction signal;
Characterized in that it includes,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 2,
The divider chain is
When a positive first signal and a negative first signal are input, a positive first signal is output when the value of the first direction signal is (+), and a negative first signal is output when the value of the first direction signal is (-). a first multiplexer outputting a first signal of;
When a positive first signal and a negative first signal are input, a negative first signal is output when the value of the first direction signal is (+), and a positive first signal is output when the value of the first direction signal is (-). a second multiplexer to which the first signal of is output;
When a positive second signal and a negative second signal are input, a negative second signal is output when the value of the second direction signal is (+), and a positive second signal is output when the value of the second direction signal is (-). a third multiplexer to which the second signal of is output; and
When a positive second signal and a negative second signal are input, a positive second signal is output when the value of the second direction signal is (+), and a negative second signal is output when the value of the second direction signal is (-). a fourth multiplexer outputting a second signal of;
Characterized in that it includes,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 1,
The injection locked oscillator is
a current source connected to ground;
a first pair of MOS transistors, one side of which is connected in parallel to the current source, and receives a (+) injection signal or (-) injection signal to each gate terminal;
a second pair of MOS transistors having one side connected to the other side of the first pair of MOS transistors and outputting a (+) output voltage signal or a (-) output voltage signal from the other side; and
a resonator having one side connected to the other side of the second pair of MOS transistors and the other side connected to a power supply voltage to generate a resonance phenomenon;
Characterized in that it includes,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 9,
The resonance part
a load inductor to which the power supply voltage is connected to a central portion; and
a variable capacitor connected in parallel to the other side of the second pair of MOS transistors and the load inductor to convert the capacitance value into a variable digital code through the resonance phenomenon at the resonance frequency;
Characterized in that it includes,
Frequency hopping spread spectrum frequency synthesizer.
According to claim 10,
The injection locked oscillator is
Characterized in that the value of the variable capacitor is adjusted with a step-by-step variable code and converted into the variable digital code.
Frequency hopping spread spectrum frequency synthesizer.

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