KR20080005836U - Signal generation device - Google Patents

Abstract

The present invention relates to a signal generator that enables the output of a wide range of frequency signals using one frequency signal.

The signal generator according to the present invention includes a reference frequency selection circuit for selectively outputting one of a fundamental frequency and one of its harmonics as a reference frequency signal, a local oscillation circuit for generating a local oscillation frequency signal, and an output from the reference frequency selection circuit. And a controller for generating an output frequency by mixing a local oscillation frequency signal output from the local oscillation circuit with respect to a reference frequency signal, and a control unit for controlling the reference frequency selection circuit and the local oscillation circuit. .

Frequency, Signal Converter

Description

Signal generation device

1 is a block diagram showing the configuration of a signal generator according to a first embodiment of the present invention;

FIG. 2 is a block diagram showing an internal configuration of the reference frequency selection circuit 1 shown in FIG.

3 is a diagram for explaining harmonic characteristics of a general frequency signal.

FIG. 4 is a block diagram showing an internal configuration of the local oscillation circuit 3 shown in FIG.

5A and 5B are block diagrams showing the configuration of a signal generator according to a second embodiment of the present invention.

******* Brief description of the main parts of the drawing *******

1: reference frequency selection circuit, 2: mixer,

3: local oscillation circuit, 4: input pad,

5: control unit.

The present invention relates to a signal generator that enables the output of a wide range of frequency signals using one frequency signal.

In general, various types of measuring devices are used in the electrical and electronic fields for experiments or product development. There are various kinds of measuring devices such as oscilloscopes and spectrum analyzers. These measuring devices are used for analyzing analog signals such as input frequency signals.

The measuring device has a wide range from about several MHz to several GHz. Therefore, the input frequency of the measuring device is required to satisfy various and wide ranges.

However, a signal generator for generating a frequency signal is usually configured to mix a local oscillation frequency with a specific frequency, wherein the range of the output frequency is limited to a certain band. Thus, there may be a method having a plurality of signal generators to generate a wide range of frequencies, but this has the disadvantage that the unit cost of the device parts is increased to lower the price competitiveness, as well as the size of the device.

Accordingly, the present invention has been made in view of the above circumstances, and has a technical purpose to provide a signal generator that can generate a wide range of frequency signals using one frequency signal with a simple configuration.

A signal generator according to the present invention for achieving the above object is a reference frequency selection circuit for selectively outputting one of the fundamental frequency and one of its harmonics as a reference frequency signal, and a local oscillation circuit for generating a local oscillation frequency signal, the reference A mixer for generating an output frequency by mixing a local oscillation frequency signal output from the local oscillation circuit with respect to a reference frequency signal output from a frequency selection circuit, and a control unit for controlling the reference frequency selection circuit and the local oscillation circuit; It is characterized in that the configuration.

In addition, the user is characterized in that the configuration further comprises an input pad for setting the range of the output frequency.

The reference frequency selection circuit may include a PLL circuit for generating a frequency signal corresponding to the control data from the controller, a first band pass filter for filtering and outputting a fundamental frequency of the frequency signal applied from the PLL circuit, and the PLL. A second band pass filter for filtering and outputting harmonic signals of a frequency signal applied from a circuit, an attenuator for attenuating and outputting a signal level of a fundamental frequency output from the first band filter, and the attenuator and the second band pass filter And a switching unit for selectively outputting a frequency signal applied from the mixer to the mixer.

The local oscillator circuit may include a PLL circuit for outputting a voltage corresponding to the control data from the controller, a voltage controlled oscillator for generating a frequency signal corresponding to the voltage output from the PLL circuit, and a voltage controlled oscillator. A frequency multiplier for multiplying a frequency signal, and a switching unit for selectively inputting the frequency signal output from the voltage controlled oscillator and the frequency multiplier to the mixer as a local oscillation frequency.

In addition, the output terminal of the frequency multiplier is characterized in that the high pass filter having a frequency pass band of 1GHz or more is configured to be combined.

That is, according to the above, by selecting the fundamental frequency and its harmonic signal as the reference frequency for one frequency signal, and selectively mixing the reference frequency and the local oscillation frequency, a wider frequency signal is generated with a simple configuration. It becomes possible to make it.

Next, an embodiment according to the present invention will be described.

1 is a block diagram showing the configuration of a signal generator according to the present invention.

In FIG. 1, the reference frequency selection circuit 1 outputs to the mixer 2 a frequency selected from the fundamental frequency or harmonics of the fundamental frequency under the control of the controller 5 to be described later.

The local oscillation circuit 3 outputs the selected local oscillation frequency to the mixer 2 under the control from the control section 5 to be described later.

The mixer 2 generates an output frequency of a desired band by mixing the frequencies input from the reference frequency selection circuit 1 and the local oscillation circuit 3.

The input pad 4 is for the user to operate the signal generator, the input pad 4 is provided with a selection button for setting the output frequency range generated by the user as in the usual equipment do.

The controller 5 performs a function of controlling the equipment as a whole. In particular, when the output frequency range is set by the input pad 4, the controller 5 appropriately controls the reference frequency selection circuit 1 and the local oscillation circuit 3 based on the set values. The control operation of the control unit 5 will be described in detail later.

FIG. 2 is a block diagram showing in detail the configuration of the reference frequency selection circuit 1 shown in FIG.

In FIG. 2, for example, a 345.6 MHz frequency signal output from the daughter PLL circuit 11 to the control data DATA1 applied from the control unit 5 is input to the switching unit 12, and the switching unit 12 controls the control unit 5. A frequency signal input in accordance with the switching signal SW1 from the?) Is selectively input to the first band pass filter (first BPF: 13) or the second band pass filter (second BPF: 14). Here, the first band pass filter 13 is set to have a fundamental frequency of a specific level frequency signal, for example, 345.6 MHz, and the second band pass filter 14 has a harmonic of the fundamental frequency, for example, a frequency pass band of 691.2 MHz. In addition, as shown in FIG. 3, in general, the frequency signal has a harmonic component (f ₁ , f ₂ ...) having an integer multiple of the fundamental frequency (f ₀ ) and the fundamental frequency (f ₀ ), and the fundamental frequency ( The signal levels I ₁ , I ₂ ,... of the harmonic components f ₁ , f ₂ ... are smaller than the signal level I ₀ of f ₀ ). Accordingly, the output signal of the first band pass filter 13 is applied to the input of the second switching unit 16 through the first attenuator 15, and the output signal of the second band pass filter 14 is second switched. It is applied to the input of the unit 16. In this case, the attenuation level of the first attenuator (15) is basically the fundamental frequency harmonics and the signal level (I ₀₎ of (f _0), (f ₁₎ signal level (I ₁₎ doedoe correspond be set to the difference value, since the mixer It may be set larger or smaller than the difference value in consideration of the frequency mixing characteristic of (2). That is, the signal level of the frequency input to the second switching unit 16 is the same. The second switching unit 16 selectively outputs a frequency signal input according to the switching signal SW2 from the control unit 5. The frequency signal output in this manner is applied to the mixer 2 through the second attenuator 17 and mixed with the local oscillation frequency signal applied from the local oscillation circuit 3.

FIG. 4 is a block diagram showing in detail the configuration of the local oscillation circuit 3 shown in FIG.

In FIG. 4, the PLL circuit 31 in the local oscillation circuit 3 has a predetermined level based on the control data DATA2 applied from the controller 5 and the oscillation frequency signal fed back from the output terminal of the voltage controlled oscillator VCO: 33. Amplifies the voltage through the amplifier 32 and outputs it. The voltage controlled oscillator 33 generates and outputs a frequency signal of, for example, 600 to 1,360 MHz so as to correspond to the input voltage. The output of the voltage controlled oscillator 33 is input to the switching unit 34, and the switching unit 34 switches the frequency signal inputted according to the switching signal SW3 applied from the control unit 5 or the frequency multiplier 35 or switching. Input to the section 37 is optional. The frequency multiplier 35 multiplies the frequency signals of the 600-1,360 MHz band input by the switching unit 34 to generate a frequency signal of the 1,200-2,720 MHz band, and the generated frequency signal is a high pass filter ( Input to the switching unit 37 via the HPF: 36. At this time, the high pass filter 36 has a frequency pass band of 1.3GHz or more. The switching unit 37 uses the frequency signal applied through the switching unit 34 or the frequency multiplier 35 and the high pass filter 36 as the local oscillation frequency in accordance with the switching signal SW4 from the control unit 5. Select and enter into mixer (2).

2 and 4, the control unit 5 controls switching of the switching units 12, 16, 34, 37 so that an output frequency set by the input pad 4 is generated.

Table 1 shows the output frequency generated by mixing the reference frequency selected by the reference frequency selection circuit 1 and the local oscillation frequency generated by the local oscillation circuit 3 through the mixer 2.

Reference frequency (MHz) Local oscillation frequency (MHz) Output frequency (MHz) 691.2 721.2 ~ 1,291.2 30-600 691.2 1,291.2-1,691.2 600-1,000 345.6 1,345.6 ~ 2,045.6 1,000-1,700 345.6 1,345.4-1,654.4 1,700-2,000 691.2 1,308.8-1,808.8 2,000-2,500 345.6 2,154.4-2,654.4 2,500-3,000

According to Table 1, 345.6 MHz and 691.2 MHz, which is a first harmonic thereof, are selected and input as a reference frequency, and between 600 to 1,360 MHz output from the voltage controlled oscillator 33 and 1,200 to 2,720 MHz, which are two multiples thereof. The frequency is selected and input as a local oscillation frequency, so that an input frequency of a wide band of 30 to 3,000 MHz can be generated.

In addition, in the above embodiment, the signal level of the fundamental frequency is made constant by the reference frequency selection circuit 1 so that the signal level of the output frequency output from the mixer 2 is kept constant. However, as shown in FIGS. 5A and 5B, the signal level of the fundamental frequency is not attenuated in the reference frequency selection circuit 1, and the third attenuator 38 is output at the output terminal of the frequency multiplier 35 in the local oscillator circuit 3. It is possible to carry out to attenuate the signal level of the local oscillation frequency mixed with the fundamental frequency.

That is, in the above-described apparatus, the fundamental frequency and its harmonic signal are selected as the reference frequency for one frequency signal, and the standard frequency and the local oscillation frequency are selectively mixed so that a wider frequency signal can be obtained with a simple configuration. It is possible to generate.

On the other hand, the present invention is not limited to the above embodiments and can be variously modified within the scope without departing from the technical spirit of the present invention.

For example, in the above embodiment, the fundamental frequency of the reference frequency is attenuated or the local oscillation frequency mixed with the fundamental frequency is attenuated. However, the local oscillation frequency amplified or mixed with the harmonic signal of the reference frequency is amplified. It is also possible to carry out amplification.

As described above, by selecting a fundamental frequency and its harmonic signal as a reference frequency for one frequency signal, and selectively mixing the reference frequency and the local oscillation frequency, it is possible to generate a wider frequency signal with a simple configuration. It becomes possible.

Claims (5)

A reference frequency selection circuit for selectively outputting one frequency of a fundamental frequency and its harmonics as a reference frequency signal, A local oscillation circuit for generating a local oscillation frequency signal, A mixer for generating an output frequency by mixing a local oscillation frequency signal output from the local oscillation circuit with respect to a reference frequency signal output from the reference frequency selection circuit; And a control unit for controlling the reference frequency selection circuit and the local oscillation circuit. The method of claim 1, Signal generating device, characterized in that the user further comprises an input pad for setting the range of the output frequency. The method of claim 1, The reference frequency selection circuit includes a PLL circuit for generating a frequency signal corresponding to the control data from the controller, a first band pass filter for filtering and outputting a fundamental frequency of a frequency signal applied from the PLL circuit, and the PLL circuit. A second band pass filter for filtering and outputting harmonic signals of an applied frequency signal, an attenuator for attenuating and outputting a signal level of a fundamental frequency output from the first band filter, and the attenuator and the second band pass filter And a switching unit for selectively outputting an applied frequency signal to the mixer. The method of claim 1, The local oscillator circuit includes a PLL circuit for outputting a voltage corresponding to the control data from the controller, a voltage controlled oscillator for generating a frequency signal corresponding to the voltage output from the PLL circuit, and a frequency signal output from the voltage controlled oscillator. And a switching unit for multiplying a frequency multiplier and multiplying the frequency signal output from the voltage controlled oscillator and the frequency multiplier to the mixer as a local oscillation frequency. The method of claim 4, wherein And a high pass filter having a frequency pass band of 1.3 GHz or more is coupled to an output terminal of the frequency multiplier.

Images