KR102480018B1 - An oscillation frequency calibration device of an injection locked oscillator - Google Patents

Abstract

The present invention discloses an oscillation frequency calibration device for an injection-locked oscillator. The device includes a multi-module divider that receives a frequency level value and outputs a divided frequency for each divided frequency level in response to a phase-locked loop frequency; a single-sideband calculator for receiving the phase-locked loop frequency signal and the divided frequency signal for each divided frequency level, adding and subtracting frequencies, and outputting them; an injection-locked oscillator for outputting an oscillation frequency signal by performing frequency hopping by converting a capacitance value having a resonant frequency at the added and subtracted frequencies into a digital code; and a frequency corrector receiving the oscillation frequency signal and matching a resonant frequency of the injection-locked oscillator with a required frequency of the injection signal to remove frequency disturbance from both bands. It is characterized in that it includes. According to the present invention, in a frequency synthesizer operating at a multi-frequency level, by minimizing a locking error and a phase noise deterioration that may occur in an injection-locked oscillator that is vulnerable to frequency fluctuations, a high-speed operation is possible with sufficient output to operate the next stage. frequency hopping is possible.

Description

An oscillation frequency calibration device of an injection locked oscillator}

The present invention relates to an oscillation frequency calibration device, and more particularly, by performing frequency calibration in both bands for rapid jumping between multi-frequency, injection-locked oscillations that can solve frequency disturbance or frequency shift problems that may occur in injection-locked oscillators. It relates to an oscillation frequency calibration device for an oscillator.

In general, as a conventional frequency synthesizer structure having frequency hopping capability, a structure based on a two-point modulation method, a frequency multiplication structure using an injection locked oscillator (ILO), and a short side wave band There is a structure based on a mixer (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 appear in the output. If a low reference frequency is used, the spurs are generated close to the signal, which makes it difficult for the injection-locked oscillator to match the desired multiple frequency, as well as stronger spurs. ) has the disadvantage of remaining as

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.

1 is a schematic block diagram of a frequency synthesizer with frequency hopping capability based on a single side band (SSB) mixer according to the prior art, comprising a phase locked loop 10, a multi-module divider 20, a single side wave band It has an arithmetic unit (30), a look-up table (40) and an injection locked oscillator (50).

Referring to FIG. 1, the operation of a frequency synthesizer having a frequency hopping capability according to the prior art will be schematically described as follows.

A phase-locked loop (PLL) 10 circuit generates a frequency-adjusted output signal using a phase difference between an input signal and a signal fed back from an output signal.

Here, 'phase synchronization' refers to controlling an oscillator or periodic signal generator to operate at a constant phase angle with respect to a reference signal source.

The multi-module divider (MMDIV, 20) receives the frequency-adjusted output signal (f _PLL ) from the phase-locked loop (10), receives multiple levels of frequency (FL), and divides the frequency (f _div ) _[FL] ) is output.

The single side wave band calculator 30 receives the frequency-adjusted output signal generated from the phase-locked loop 10 and the divided frequency f _{div [FL]} output from the multi-module divider 20 as inputs, and calculates the frequency Add and subtract.

The injection locked oscillator (ILO, 50) converts the capacitance value having the frequency added or subtracted from the single side wave band operator 30 as the resonant frequency into a digital code, and performs frequency hopping to obtain an oscillation frequency signal (f) _ILO ) is output.

Also, after extracting multiple frequencies of the reference frequency, the capacitance is instantaneously changed to match one of them.

At this time, the lookup table (LuT, 40) stores the digital capacitance value corresponding to the increased code in the form of a code.

That is, the look-up table 40 stores the oscillator tuning word (OTW) required by receiving a plurality of levels of frequencies FL, and then outputs it to the injection-locked oscillator 50.

In this case, the injection-locked oscillator 50 operates as a regenerative amplifier. Due to a frequency disturbance or frequency drift problem, lock failure and phase noise deterioration (Phase Noise Degradation) phenomenon occurs.

By outputting an oscillation frequency signal (f _ILO ) that is not required by the injection-locked oscillator 50, there is a limit to eventually producing an output that is insufficient to operate the next stage.

In addition, in order to obtain an output of the injection-locked oscillator 50 suitable for the injection signal, a desired operation cannot be obtained when the resonant frequency of the injection-locked oscillator 50 is greatly different from the injection signal.

This is because, due to the characteristics of the injection-locked oscillator 50, a locking range exists around the self-oscillation frequency, and the injection-locked oscillator 50 is vulnerable to frequency variation at multi-frequency levels.

Accordingly, for high-speed frequency hopping, a high-speed calibration circuit is required to match the resonant frequency of the injection-locked oscillator 50 with the frequency of the required injection signal.

Korean Patent Publication KR 10-2006-0041377 A

An object of the present invention is to match the resonance frequency of an injection-locked oscillator in a frequency synthesizer with the frequency of an injection signal to perform frequency correction in both bands for rapid jumping between multi-frequency, thereby solving the problem of frequency disturbance or frequency shift fatal to the operation of the injection-locked oscillator. It is an object of the present invention to provide an oscillation frequency calibration device for an injection-locked oscillator capable of solving

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.

An oscillation frequency calibration device of an injection-locked oscillator of the present invention for achieving the above object includes a multi-module divider for receiving a frequency level value and outputting a divided frequency for each divided frequency level in response to a phase-locked loop frequency; a single-sideband calculator for receiving the phase-locked loop frequency signal and the divided frequency signal for each divided frequency level, adding and subtracting frequencies, and outputting them; an injection-locked oscillator for outputting an oscillation frequency signal by performing frequency hopping by converting a capacitance value having a resonant frequency at the added and subtracted frequencies into a digital code; and a frequency corrector receiving the oscillation frequency signal and matching a resonant frequency of the injection-locked oscillator with a required frequency of the injection signal to remove frequency disturbance from both bands. It is characterized in that it includes.

An apparatus for calibrating the oscillation frequency of an injection-locked oscillator of the present invention for achieving the above object includes a look-up table for storing a digital capacitance value corresponding to a digital code updated in the injection-locked oscillator; and an injection signal switch for opening or shorting a connection path between the single-sideband operator and the injection-locked oscillator. It is characterized in that it further comprises.

In the injection-locked oscillator of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object, when the injection signal switch is turned off, the connection path is opened, so that the resonance frequency of the injection-locked oscillator is set to the reference frequency. The digital capacitance value is updated to match one of the multiple frequencies of , and when the injection signal switch is turned on, the connection path is shorted, so that the injection locked oscillator receives the added or subtracted frequency to perform the frequency hopping. characterized by running.

The frequency calibrator of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object temporarily stops the application of the injection signal to the injection-locked oscillator while the connection path is open, and the look-up table It is characterized in that the oscillation frequency signal is calibrated by updating the oscillator tuning word so that the required oscillator tuning word is stored.

The frequency calibrator of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object changes the frequency of the oscillation frequency signal according to Equation 1 below, [Equation 1] f _ILO = f _PLL + FL*f _ref Here, f _PLL is a phase-locked loop frequency value, FL is a frequency level value, and f _ref is a reference frequency value.

The frequency calibrator of the oscillation frequency calibrating device of the injection-locked oscillator of the present invention for achieving the above object includes a double-sided wave band operator for receiving the phase-locked loop frequency signal and the oscillation frequency signal, adding and subtracting frequencies, and outputting them; a plurality of buffers receiving the added and subtracted frequencies and outputting a shift frequency signal by delaying a predetermined time; a frequency divider for receiving the frequency level value and dividing frequencies in response to control of the shift frequency signal and the phase-locked loop frequency signal to output a reference frequency and a normalized frequency; a counting unit receiving the divided reference frequency and the normalized frequency and counting and outputting the number of pulse edges; an adder or subtractor that receives the output signal of the counting unit and adds or subtracts the output signal; a comparator receiving the output signal of the adjuster and outputting a code output signal in response to control of the reference frequency delay signal; and a D flip-flop receiving the code output signal, latching the code output signal in response to a clock signal, and outputting the latched code output signal to the lookup table.

The look-up table of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object receives the latched code output signal and sums the code output signal in response to a clock signal to output an oscillator tuning word signal characterized by

In order to achieve the above object, the frequency calibrator of the oscillation frequency calibration device of the injection-locked oscillator of the present invention needs to store the oscillator tuning word signal in the look-up table in the lower band of the both bands, code signal for each frequency level It is characterized in that it further comprises a; swapper for exchanging the input of the adjuster in response to the control of the counting unit and the adjuster.

The frequency divider of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object receives the frequency level value and divides according to the division rate for each frequency level value in response to control of the shift frequency signal a normalized frequency divider for outputting the normalized frequency; and a reference frequency divider configured to divide the phase-locked loop frequency signal according to a fixed frequency division ratio and output the reference frequency in response to control of the phase-locked loop frequency signal.

The frequency divider of the oscillation frequency calibration device of the injection-locked oscillator of the present invention for achieving the above object includes a first counter for receiving the divided reference frequency and counting the number of pulse edges for a predetermined time; and a second counter receiving the divided normalized frequency and counting the number of pulse edges for a time equal to the predetermined time.

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, in a frequency synthesizer operating at a multi-frequency level, by minimizing a locking error and a phase noise deterioration that may occur in an injection-locked oscillator that is vulnerable to frequency fluctuations, a high-speed operation is possible with sufficient output to operate the next stage. frequency hopping is possible.

In addition, since the previously stored value is called when the frequency level value changes during the calibration process in the upper band, the lookup table can maintain a locked state, so that the injection signal is not vulnerable to frequency fluctuations as it exists within the locked range. .

In addition, no additional time is consumed in the calibration process in the lower band, enabling operation without seam waveforms that may appear on the output of the injection-locked oscillator.

Figure 1 is a schematic block diagram of a frequency synthesizer with frequency hopping capability based on a single side wave band (SSB) mixer according to the prior art.
2 is a block diagram of an oscillation frequency calibration device for an injection-locked oscillator according to an embodiment of the present invention.
FIG. 3 is a graph of a change in the resonant frequency of the injection-locked oscillator 600 according to locking of the injection signal versus time of the oscillation frequency calibration device shown in FIG. 2 .
FIG. 4 is a graph of a change in the resonant frequency of the injection-locked oscillator 600 according to application of an injection signal versus time of the oscillation frequency calibration device shown in FIG. 2 .
Figure 5 is a detailed block diagram of the oscillation frequency calibration device of the present invention shown in Figure 2.
FIG. 6 is a block diagram for explaining an operation when the injection signal switch 400 is turned off in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .
FIG. 7 is a block diagram for explaining an operation when the injection signal switch 400 is turned on in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .
8 is a block diagram for explaining an operation in which oscillation frequency calibration is performed in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .
FIG. 9 is a block diagram for explaining some operations in which oscillation frequency calibration is performed in an upper-sideband in the oscillation frequency calibrating apparatus of the present invention shown in FIG. 8 .
FIG. 10 is a graph of output changes of the first and second counters 741 and 742, the comparator 760, and the lookup table 500 versus time, as a result of simulation of the oscillation frequency calibration device shown in FIG. 5 .
FIG. 11 shows simulation results of the oscillation frequency calibrating device shown in FIG. 5 and the output change of the comparator 760 according to the lead-lag reversion phenomenon in the first and second counters 741 and 742. is a graph for
FIG. 12 is a block diagram for explaining some operations in which oscillation frequency calibration is performed in a lower-sideband in the detailed block diagram of the apparatus for calibrating the oscillation frequency of the present invention shown in FIG. 5 .
FIG. 13 is a waveform diagram of a simulation result in an upper band of the oscillation frequency calibrating device shown in FIG. 5 .
FIG. 14 is a waveform diagram of a simulation result in a lower band of the oscillation frequency calibrating device 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.

2 is a block diagram of an oscillation frequency calibration device of an injection-locked oscillator according to an embodiment of the present invention, comprising a phase-locked loop 100, a multi-module divider 200, a single-sideband operator 300, and an injection signal switch. (400), a lookup table (500), an injection locked oscillator (600) and a frequency calibrator (700).

FIG. 3 is a graph of a change in the resonant frequency of the injection-locked oscillator 600 according to locking of the injection signal versus time of the oscillation frequency calibration device shown in FIG. 2 .

FIG. 4 is a graph of a change in the resonant frequency of the injection-locked oscillator 600 according to application of an injection signal versus time of the oscillation frequency calibration device shown in FIG. 2 .

Referring to FIGS. 2 to 4, the operation according to the locking and application of the injection signal of the oscillation frequency calibration device of the present invention shown in FIG. 2 will be described schematically as follows.

In FIG. 2 , when the injection signal switch 400 is turned off, a connection path between the single side wave band operator 300 and the injection locked oscillator 600 is opened.

Accordingly, the injection-locked oscillator 600 does not receive the frequency added or subtracted from the single side wave band calculator 300, and updates the capacitance to match one of multiple frequencies of the reference frequency.

In addition, the lookup table 500 receives a digital capacitance value corresponding to a code updated by the injection-locked oscillator 600 through the frequency calibrator 700 and stores it in a code form.

Therefore, as shown in FIG. 3(b), a seam waveform (shown in gray) that requires some settling time at the beginning of the oscillation frequency signal f _ILO output from the injection-locked oscillator 600 is appear.

On the other hand, when the injection signal switch 400 in FIG. 2 is turned on, a connection path between the single side wave band operator 300 and the injection locked oscillator 600 is shorted.

Accordingly, the injection-locked oscillator 600 receives the frequency added or subtracted from the single side wave band operator 300, converts the capacitance value used as the resonant frequency into a digital code, and performs frequency hopping.

In addition, since the lookup table 500 updates the capacitance by receiving the stored oscillator tuning word, that is, the already calibrated frequency, additional setting time is hardly consumed.

Accordingly, as shown in FIG. 4(b), the oscillation frequency signal f _ILO output from the injection-locked oscillator 600 shows a smooth signal (shown in light blue) without a seam waveform.

FIG. 5 is a detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 2, comprising a phase-locked loop 100, a multi-module divider 200, a single side wave band operator 300, and an injection signal switch 400. , a lookup table 500, an injection locked oscillator 600 and a frequency calibrator 700.

The frequency calibrator 700 includes a double-sideband (DSB) 710, a plurality of buffers 720, a frequency divider 730, a counting unit 740, an adder 750, and a comparator 760. and D-flip-flop 770.

In addition, the frequency divider 730 includes a normalization frequency divider 731 and a reference frequency divider 732, and the counting unit 740 includes a first counter 741 and a second counter 742. .

FIG. 6 is a block diagram for explaining an operation when the injection signal switch 400 is turned off in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .

FIG. 7 is a block diagram for explaining an operation when the injection signal switch 400 is turned on in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .

8 is a block diagram for explaining an operation in which oscillation frequency calibration is performed in the detailed block diagram of the oscillation frequency calibration device of the present invention shown in FIG. 5 .

FIG. 9 is a block diagram for explaining some operations in which oscillation frequency calibration is performed in an upper-sideband in the oscillation frequency calibrating apparatus of the present invention shown in FIG. 8 .

FIG. 10 is a graph of output changes of the first and second counters 741 and 742, the comparator 760, and the lookup table 500 versus time, as a result of simulation of the oscillation frequency calibration device shown in FIG. 5 .

FIG. 11 shows simulation results of the oscillation frequency calibrating device shown in FIG. 5 and the output change of the comparator 760 according to the lead-lag reversion phenomenon in the first and second counters 741 and 742. is a graph for

FIG. 12 is a block diagram for explaining some operations in which oscillation frequency calibration is performed in a lower-sideband in the detailed block diagram of the apparatus for calibrating the oscillation frequency of the present invention shown in FIG. 5 .

FIG. 13 is a waveform diagram of a simulation result in an upper band of the oscillation frequency calibrating device shown in FIG. 5 .

FIG. 14 is a waveform diagram of a simulation result in a lower band of the oscillation frequency calibrating device shown in FIG. 5 .

The operation according to the locking and application of the injection signal of the oscillation frequency calibration device according to the present invention will be described in detail with reference to FIGS. 5 to 14 .

As shown in FIG. 6, when the injection signal switch 400 is turned off, the injection signal is not applied to the injection locked oscillator 600 and only DC bias is output, and the lookup table 500 is updated to obtain required oscillator tuning. Causes word (OTW[FL]) to be stored.

In addition, as shown in FIG. 8 , an oscillation frequency correction operation is performed to remove frequency disturbance generated in the oscillation frequency signal f _ILO output from the injection-locked oscillator 600 .

That is, in a steady state, the normalized frequency value (f _norm[FL] ) that is the output of the normalized frequency divider 731 of the upper band according to the frequency feedback is the reference frequency that is the output of the reference frequency divider 732. It is almost identical to the value (f _ref ).

However, when frequency calibration is performed by the oscillation frequency calibration device of the present invention, the oscillation frequency signal f _ILO output from the injection-locked oscillator 600 is changed as in Equation 1 below.

[Equation 1]

f _ILO = f _PLL + FL*f _ref

Here, f _PLL is a phase-locked loop frequency value, FL is a frequency level value, and f _ref is a reference frequency value.

That is, as shown in FIG. 9, when the phase-locked loop frequency (f _PLL ) is 60 GHz and the output frequency value (f _ref ) of the reference frequency divider 732 is 1 GHz along the path marked in black, the red mark Since the frequency level (FL) value becomes 3 according to the path, the oscillation frequency signal f _ILO of the injection-locked oscillator 600 is calculated as 63 GHz by Equation 1 above.

Therefore, when frequency calibration is performed by the oscillation frequency calibration device of the present invention, the injection-locked oscillator 600 operates like a DC oscillator in a downmixing phase-locked loop.

The slopes of the outputs of the first and second counters 741 and 742 in the oscillation frequency calibrating apparatus shown in FIG. 5 mean frequencies, and a plurality of frequencies are compared by signs of the adder 750.

In addition, the adder 750 performs a subtraction operation by receiving the outputs of the first and second counters 741 and 742, and the comparator 760 outputs the output according to the control of the reference frequency delay signal f _ref.delay The size of the frequency may be compared through information of the sign output signal (Sign out), and the oscillator tuning word (OTW) may be adjusted.

That is, in the intervals (T1 to T3, T5, T7) in which the slope of the output (red) of the second counter 742 is greater than the slope of the output (black) of the first counter 741 in FIG. 10 (a), FIG. At 10(b), the sign output signal Sign out of the comparator 760 is output at a high level.

Accordingly, the D flip-flop 770 latches the high-level sign output signal (Sign out) in response to the control of the clock signal (CLK) to output a high-level signal delayed by a predetermined time, and uses the look-up table 500 receives this signal and sums it up in response to control of the clock signal, thereby outputting the oscillator tuning word signal OTW as in the intervals T1 to T3, T5 and T7 of FIG. 10(c).

On the other hand, in the intervals T4 and T6 in which the slope of the output (red) of the second counter 742 is smaller than the slope of the output (black) of the first counter 741 in FIG. 10 (a), FIG. 10 (b) At , the sign output signal Sign out of the comparator 760 is output at a low level.

Accordingly, the D flip-flop 770 latches the low-level sign output signal (Sign out) in response to the control of the clock signal to output a low-level signal delayed by a predetermined time, and the look-up table 500 is received and summed in response to the control of the clock signal, thereby outputting the oscillator tuning word signal OTW as in the sections T4 and T6 of FIG. 10(c).

Meanwhile, by comparing the phases of the first and second counters 741 and 742 with respect to the rising edge of the clock signal CLK in order to increase the tuning resolution of the oscillator tuning word signal OTW, Ideally, a resolution equal to the frequency of the clock signal CLK can be obtained.

That is, in FIG. 5, the normalized frequency divider 731 in the frequency divider 730 controls the shift frequency signal f _dev[FL] delayed through the plurality of buffers 720 by receiving the frequency level FL value. In response, the normalized frequency (f _norm[FL] ) is output by dividing according to the division rate for each frequency level (FL) value.

In addition, the reference frequency divider 732 in the frequency divider 730 outputs the reference frequency f _ref by dividing according to a fixed dividing ratio in response to the control of the phase-locked loop frequency signal f _PLL .

The first counter 741 in the counting unit 740 receives the reference frequency f _ref output from the reference frequency dividing unit 732 and counts the number of pulse edges for a certain period of time, and the second counter ( 742) receives the normalized frequency (f _norm[FL] ) output from the normalized frequency divider 731 and counts the number of pulse edges during the same time period.

The output signals of the first and second counters 741 and 742 counted in this way appear as a black waveform and a red waveform, respectively, as shown in FIG. 11 (a), and lead-lag reversion at time point t1 phenomenon occurs.

Accordingly, the sign output signal Sign out of the comparator 760 toggles from a high level to a low level at a time point t1 as shown in FIG. 11(b).

Next, in order to perform oscillation frequency calibration in the lower-sideband of the oscillation frequency calibration device of the present invention shown in FIG. 5, a block diagram of the frequency calibrator 700 in the oscillation frequency calibration device shown in FIG. should be changed as shown in FIG.

That is, in the block diagram of the frequency calibrator 700 shown in FIG. 5, a swapper 745 is added between the counting unit 740 and the adder 750.

The swapper 745 converts the sign signal SIGN(SIGN( In response to the control of FL)), the input of the adjuster 750 is swapped.

Here, the sign signal SIGN(FL) for each frequency level FL controls to output a (+) signal in the upper-sideband and a (-) signal in the lower-sideband. It's a signal.

Through this, since the oscillation frequency calibration device of the present invention loads and updates the result already calibrated in the lower-sideband, almost no additional time is consumed, so that the output of the injection lock oscillator 600 is the injection signal A seamless operation is possible so that the applied path is not easily disconnected for a moment.

13 is a waveform diagram of a simulation result in an upper band of the oscillation frequency calibration device shown in FIG. 5, including a frequency level signal FL, an oscillator tuning word signal OTW(FL) for each frequency level FL, and an injection lock oscillator 600 of the oscillation frequency signal f _ILO and the normalization frequency divider 731 of the frequency signal f _norm .

As shown in FIG. 13, it can be seen that the oscillator tuning word signal (OTW) converges to a constant value as the frequency level (FL) value varies from 2 to 4. In the upper band, the frequency level (FL) When the value changes, the previously saved value is called, so additional tuning, that is, locking time, is not required.

Accordingly, in the period from 3.6 to 4.2 ns, the oscillator tuning word signal OTW maintains a locked state with values 13 to 14, and the output frequency value f _norm of the normalized frequency divider 731 is the reference frequency It converges to 1 GHz, which is the output frequency value (f _ref ) of the divider 732.

In addition, it can be seen that the oscillation frequency signal f _ILO output from the injection-locked oscillator 600 converges to the required frequency of 63 GHz in the interval where the frequency level (FL) value is 3, which is It can be seen that it is the same as the value calculated in .

At this time, in the upper band, the lookup table 500 is updated from the previous state in every tuning process, and the time required for frequency tuning is less than 100 ns.

14 is a waveform diagram of simulation results in the lower band of the oscillation frequency calibration device shown in FIG. 5, including a frequency level signal FL, an oscillator tuning word signal OTW(FL) for each frequency level FL, and an injection lock oscillator 600 of the oscillation frequency signal f _ILO and the normalization frequency divider 731 of the frequency signal f _norm .

The peculiarity of the calibration operation in the lower band is that since the initial value of the oscillator tuning word signal OTW(FL) was '0', as shown in FIG. 14, the oscillator tuning word value changes from 'zero' to 'full'. It can be seen that the oscillation frequency signal f _ILO of the injection-locked oscillator 600 and the frequency signal f _norm of the normalization frequency divider 731 output peak values at the turn around time.

As such, the present invention matches the resonance frequency of the injection-locked oscillator in the frequency synthesizer to the frequency of the injection signal and performs frequency correction in both bands for rapid jump between multi-frequency, thereby preventing frequency disturbance or frequency shift fatal to the operation of the injection-locked oscillator. An oscillation frequency correction device for an injection-locked oscillator capable of solving the problem is provided.

Through this, the present invention minimizes the locking error and phase noise deterioration that may occur in the injection-locked oscillator, which is vulnerable to frequency fluctuations in the frequency synthesizer operating at multi-frequency levels, so that it has sufficient output to operate the next stage and high-speed frequency can make a leap.

In addition, since the previously stored value is called when the frequency level value changes during the calibration process in the upper band, the lookup table can maintain a locked state, so that the injection signal is not vulnerable to frequency fluctuations as it exists within the locked range. .

In addition, no additional time is consumed in the calibration process in the lower band, enabling operation without seam waveforms that may appear on the output of the injection-locked oscillator.

In the above, several preferred embodiments of the present invention have been described with some examples, but the description of the various embodiments described in the "Specific Contents for Carrying Out the Invention" section is merely illustrative, 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 completely 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.

100: phase locked loop
200: multi-module divider
300: single side wave band calculator
400: injection signal switch
500: lookup table
600: injection lock oscillator
700, 700': frequency corrector
710: double-sided band calculator
720: multiple buffers
730: frequency divider
731: normalization frequency divider
732: reference frequency divider
740: counting unit
741: first counter
742: second counter

Claims (10)

a multi-module divider that receives a frequency level value and outputs a divided frequency for each divided frequency level in response to a phase-locked loop frequency;
a single-sideband calculator for receiving the phase-locked loop frequency signal and the divided frequency signal for each divided frequency level, adding and subtracting frequencies, and outputting them;
an injection-locked oscillator for outputting an oscillation frequency signal by performing frequency hopping by converting a capacitance value having a resonant frequency at the added and subtracted frequencies into a digital code; and
a frequency calibrator receiving the oscillation frequency signal and matching a resonant frequency of the injection-locked oscillator with a required injection signal frequency to remove frequency disturbance from both bands;
a look-up table for storing a digital capacitance value corresponding to a digital code updated in the injection-locked oscillator; and
an injection signal switch that opens or shorts a connection path between the single-sideband calculator and the injection-locked oscillator;
Including,
The frequency corrector is
a double-sided band calculator for receiving the phase-locked loop frequency signal and the oscillation frequency signal, adding and subtracting frequencies, and outputting the added and subtracted frequencies;
a plurality of buffers receiving the added and subtracted frequencies and outputting a shift frequency signal by delaying a predetermined time;
a frequency divider for receiving the frequency level value and dividing frequencies in response to control of the shift frequency signal and the phase-locked loop frequency signal to output a reference frequency and a normalized frequency;
a counting unit receiving the divided reference frequency and the normalized frequency and counting and outputting the number of pulse edges;
an adder or subtractor that receives the output signal of the counting unit and adds or subtracts the output signal;
a comparator receiving the output signal of the adjuster and outputting a code output signal in response to control of the reference frequency delay signal; and
a D flip-flop receiving the code output signal, latching the code output signal in response to a clock signal, and outputting the latched code output signal to the lookup table;
Characterized in that it includes,
An oscillation frequency correction device for an injection-locked oscillator. delete According to claim 1,
The injection locked oscillator is
When the injection signal switch is turned off, the connection path is opened to update a digital capacitance value such that a resonant frequency of the injection locked oscillator matches one of multiple frequencies of a reference frequency;
Characterized in that, when the injection signal switch is turned on, the connection path is shorted, so that the injection locked oscillator receives the added or subtracted frequency and executes the frequency hopping.
An oscillation frequency correction device for an injection-locked oscillator.
According to claim 3,
The frequency corrector is
In the state where the connection path is open, the application of the injection signal to the injection-locked oscillator is temporarily stopped, and the oscillation frequency signal is calibrated by updating the look-up table so that the required oscillator tuning word is stored. doing,
An oscillation frequency correction device for an injection-locked oscillator.
According to claim 4,
The frequency corrector is
Changing the frequency of the oscillation frequency signal f _ILO according to Equation 1 below,
[Equation 1]
f _ILO = f _PLL + FL*f _ref
Here, f _PLL is a phase-locked loop frequency value, FL is a frequency level value, and f _ref is a reference frequency value.
An oscillation frequency correction device for an injection-locked oscillator.
delete According to claim 1,
The lookup table is
Characterized in that the latched code output signal is received and an oscillator tuning word signal is output by summing the code output signal in response to a clock signal.
An oscillation frequency correction device for an injection-locked oscillator.
According to claim 7,
The frequency corrector is
a swapper for exchanging inputs of the modulator in response to control of a code signal for each frequency level when it is necessary to store the oscillator tuning word signal in the lookup table in the lower band of the both bands;
Characterized in that it further comprises between the counting unit and the adjuster,
An oscillation frequency correction device for an injection-locked oscillator.
According to claim 1,
The frequency divider is
a normalized frequency divider configured to receive the frequency level value and output the normalized frequency by dividing the frequency according to a division rate for each frequency level value in response to control of the shift frequency signal; and
a reference frequency dividing unit dividing the phase-locked loop frequency signal according to a fixed frequency division ratio in response to control of the phase-locked loop frequency signal and outputting the reference frequency;
Characterized in that it includes,
An oscillation frequency correction device for an injection-locked oscillator.
According to claim 9,
The frequency divider is
a first counter receiving the divided reference frequency and counting the number of pulse edges for a predetermined period of time; and
a second counter receiving the divided normalized frequency and counting the number of pulse edges for a time equal to the predetermined time;
Characterized in that it includes,
An oscillation frequency correction device for an injection-locked oscillator.

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