KR20050119418A - Oscillator - Google Patents

Abstract

The voltage controlled current source 58 outputs an oscillator drive current 308 and an oscillator equivalent current 326. The signal oscillation circuit 60 outputs the first original oscillation signal 310 and the second original oscillation signal 312. The differential amplifier 52 outputs the first amplified oscillation signal 314 and the second amplified oscillation signal 316. The first switch circuit 62 and the second switch circuit 64 output the first current oscillation signal 320 and the second current oscillation signal 322, respectively. The first current value conversion amplification circuit 66 converts the value of the first current oscillation signal 320, and the second current value conversion amplification circuit 68 converts the value of the second current oscillation signal 322, Finally, the output current becomes. The adder 56 outputs the differential amplifier drive current 324 obtained by adding the oscillator equivalent current 326 and the conversion equivalent current 328 to the differential amplifier 52.

Description

Oscillator Circuit {OSCILLATOR}

The present invention relates to an oscillation circuit. In particular, the present invention relates to an oscillation circuit capable of changing oscillation frequency.

A voltage controlled oscillation circuit is used, for example, for an optical pickup or a phase locked loop (PLL). In general, the oscillation frequency is changed and set according to a control voltage applied to oscillate and output a signal having the oscillation frequency. One example of the voltage-controlled oscillator in the prior art connects the inverting amplifier, the first charge / discharge circuit, and the second charge / discharge circuit in a single order. In this configuration, the phase of the inverted voltage signal from the inverting amplifier is delayed step by step in the first charging and discharging circuit and the second charging and discharging circuit, and the output of the second charging and discharging circuit is again input to the inverting amplifier. Since the phase of the pure inverted voltage signal becomes the same as the original phase again, the voltage controlled oscillator can be oscillated continuously by repeating the above process. In addition, the oscillation frequency of the voltage controlled oscillator is mainly determined by the magnitude of the charge / discharge current in the first charge / discharge circuit and the second charge / discharge circuit, and the magnitude of the charge / discharge current is a current value level larger than the charge / discharge current. The control is controlled by easy control current.

References: Japanese Patent Laid-Open No. 6-37599

In the prior art, since the control is performed by the control current even when the charge / discharge current is very small, it is possible to stably oscillate even at a low oscillation frequency by stabilizing the current value level for control. On the other hand, in general, at high oscillation frequency, the following subjects need further examination. When oscillating an oscillation signal having a high oscillation frequency and amplifying the oscillation signal by a field effect transistor (FET) (hereinafter referred to as "amplification FET"), the amplification FET flows. If the current is small, the operation speed of the amplifying FET is slowed down, so that the oscillation signal is not sufficiently amplified. However, in order to sufficiently amplify the high oscillation frequency oscillation signal, when the current flowing through the amplification FET is increased, more power than necessary is consumed when amplifying the low oscillation frequency oscillation signal instead of the high oscillation frequency.

On the other hand, for a provider in which an oscillation circuit is incorporated in a large scale integrated circuit (LSI) or the like and provided, it is preferable that the LSI can be used universally in order to obtain a mass production effect. In addition, a user who mounts the LSI in a device or the like needs a signal output of sufficient amplitude at an oscillation frequency set in the device, and therefore, the user wants to operate with low power consumption. For this purpose, the oscillation circuit is required to have appropriate characteristics such as signal output and power consumption in a wide oscillation frequency range. In particular, when the user applies the oscillation circuit in a predetermined apparatus, and the oscillation frequency changes in accordance with a predetermined setting during the use of the apparatus, it is possible to satisfy predetermined requirements regarding signal output or power consumption for each oscillation frequency. There is a need.

The present inventors have realized such a situation, and have realized the present invention, and an object thereof is to provide an oscillation circuit in which the characteristics of the oscillation signal are improved and power consumption is lowered according to the oscillation frequency.

One embodiment of the present invention is an oscillation circuit. This oscillation circuit is capable of setting an oscillation frequency of an oscillation signal, a differential oscillation signal generation circuit for outputting an oscillation signal having an oscillation frequency set as a differential signal, a differential amplifier for differentially amplifying an oscillation signal output as a differential signal, and differential amplification A conversion amplifier circuit for converting and amplifying the voltage of one oscillation signal into a current, and a frequency dependent adjustment circuit for adjusting the operating characteristics of the differential amplifier according to the setting contents of the differential oscillation signal generating circuit.

The amplification ratio in the "differential amplifier" may be appropriately set in accordance with the circuit. For example, when the amplification ratio is greater than "1", when the amplification ratio is "1", and the amplification ratio is smaller than "1", We shall include.

The "setting content" indicates a setting relating to the oscillation frequency, and the setting is made based on a current value, a voltage value, or other signal.

In the differential oscillation signal generation circuit, when the oscillation frequency of the oscillation signal is set high, the frequency dependent adjustment circuit may speed up the operation of the differential amplifier.

"Set high" is made according to the magnitude | size of a voltage value, a current value, or a predetermined signal, but it is supposed that an oscillation frequency should finally become high.

The oscillation circuit can adjust the operating characteristics of the differential amplifier according to the oscillation frequency of the oscillation signal. Therefore, when the oscillation frequency is high, the differential amplifier operates at a higher speed, and thus it is possible to output an oscillation signal having a high oscillation frequency. In addition, since the differential signal is processed, the distortion component of the signal is canceled even at a high oscillation frequency, and the distortion component of the signal is reduced.

The differential oscillation signal generating circuit includes a differential ring oscillator and a driving circuit for driving the driving current according to the setting contents for the differential ring oscillator, and the frequency dependent adjusting circuit causes the current according to the driving current to flow to the differential amplifier, The amplifier may be operated.

Another aspect of the present invention is also an oscillation circuit. The oscillation circuit includes a differential oscillation signal generation circuit for outputting a predetermined oscillation signal as a differential signal, a differential amplifier for differentially amplifying the oscillation signal output as a differential signal, and amplifying the voltage of the differentially amplified oscillation signal by converting it into a current. The conversion amplifier circuit, the setting circuit which sets the conversion characteristic of a conversion amplifier circuit, and the output dependent adjustment circuit which adjusts the operating characteristic of a differential amplifier according to the setting content of a setting circuit are included.

In the setting circuit, when the current for converting the voltage of the oscillation signal into a current is set large, the output dependent adjusting circuit may speed up the operation of the differential amplifier.

Since the oscillation circuit can adjust the operating characteristics of the differential amplifier according to the setting for converting the voltage of the oscillation signal into a current, for example, the oscillation signal can be enlarged and output by a high speed operation of the differential amplifier. Do.

Furthermore, since this summary of the invention does not necessarily describe all essential features, the invention may also be a sub-combination of these described features.

The present invention is not intended to limit the scope of the invention, but is described based on preferred embodiments that illustrate the invention. All of the features and the combinations described in the embodiments are not necessarily essential to the invention.

(Embodiment 1)

Embodiment 1 manufactures high frequency oscillation on the premise that a manufacturer can oscillate a wide range of oscillation frequency oscillation signals for the purpose of versatility, and sets it to a predetermined oscillation frequency by a user. It is about a circuit. The high frequency oscillation circuit in this embodiment changes the oscillation frequency of the oscillation signal in accordance with the applied control voltage. For example, if the control voltage is high, the oscillation frequency is high, and if the control voltage is low, the oscillation frequency is low. In addition, the amplitude of the voltage of the oscillation signal is sufficiently amplified by the amplifying FET, and the voltage of the amplified oscillation signal is converted into a current. In particular, the high frequency oscillation circuit according to the present embodiment increases the current flowing through the amplifying FET when the control voltage is set high, so that the amplifying FET can be operated at high speed when the oscillation frequency is high. On the other hand, when the oscillation frequency is low, the current flowing through the amplification FET can be reduced, so that power consumption can be reduced.

1 shows a high frequency oscillation circuit 100 according to the first embodiment. The high frequency oscillation circuit 100 includes a voltage controlled oscillation circuit 50, a differential amplifier 52, a conversion amplifier circuit 54, and an adder 56, and the voltage controlled oscillation circuit 50 includes a voltage controlled current source 58. And a signal oscillation circuit 60, the conversion amplifier circuit 54 includes a first switch circuit 62, a second switch circuit 64, a first current value conversion amplifier circuit 66, and a second current value. The conversion amplifier circuit 68 and the constant current source 70 are included. As a signal, the control voltage 306, the oscillator driving current 308, the first original oscillation signal 310, the second original oscillation signal 312, the first amplified oscillation signal 314, the second amplified oscillation signal ( 316, the constant current 318 for conversion, the first current oscillation signal 320, the second current oscillation signal 322, the differential amplifier drive current 324, the oscillator equivalent current 326, the conversion equivalent current 328 It includes.

The voltage controlled current source 58 applies a control voltage 306 and flows the oscillator drive current 308 and the oscillator equivalent current 326 according to the magnitude of the control voltage 306. Here, the magnitudes of the oscillator drive current 308 and the oscillator equivalent current 326 have a proportional relationship, and both of them become larger as the control voltage 306 increases.

The signal oscillation circuit 60 outputs the first original oscillation signal 310 and the second original oscillation signal 312 of the oscillation frequency according to the magnitude of the oscillator driving current 308. Specifically, when the oscillator drive current 308 becomes large, the oscillation frequency is set high. The first original oscillation signal 310 or the second original oscillation signal 312 may repeatedly appear in a predetermined period, for example, a maximum value and a minimum value like a sinusoidal wave, and may be subjected to differential amplification processing in the differential amplifier 52 described later. To do this, a balance signal is constructed. In addition, a "balance signal" represents a differential signal, while an "unbalance signal" shall represent a normal signal based on ground or the like.

The differential amplifier 52 differentially amplifies the first original oscillation signal 310 and the second original oscillation signal 312, respectively, and outputs a first amplified oscillation signal 314 and a second amplified oscillation signal 316. . The differential amplification process is executed for the purpose of increasing the drive capability in the first switch circuit 62 or the second switch circuit 64, which will be described later. The first amplified oscillation signal 314 or the second amplified oscillation signal 316 has the same waveform as the first original oscillation signal 310 or the second original oscillation signal 312, and constitutes a balance signal. In addition, the amplification FET described above is included in the differential amplifier 52.

The constant current source 70 supplies a conversion constant current 318 for converting the voltage of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 into a current. Here, the conversion constant current 318 is defined as a constant value, and also the conversion equivalent current 328 having a proportional relationship with the conversion constant current 318 is output.

The first switch circuit 62 converts the first amplified oscillation signal 314 into a first current oscillation signal 320. Here, when the value of the first amplified oscillation signal 314 is large, the value of the first current oscillation signal 320 is close to the value of the constant current 318 for conversion, and the value of the first amplified oscillation signal 314 is small. In this case, the value of the first current oscillation signal 320 becomes smaller. The second switch circuit 64 also operates in the same manner as the first switch circuit 62 to convert the second amplified oscillation signal 316 into a second current oscillation signal 322.

The first current value conversion amplifier circuit 66 converts the value of the first current oscillation signal 320, and the second current value conversion amplifier circuit 68 converts the value of the second current oscillation signal 322. Here, the converted first current oscillation signal 320 corresponds to the source current, the value of the converted second current oscillation signal 322 corresponds to the sink current, and the first switch circuit 62 and the second switch circuit. Based on the switching in 64, the sink current and the source current become the switched output current. Here, "output current" shall include "sink current" and "source current".

The adder 56 causes the differential amplifier 52 to flow the differential amplifier drive current 324 plus the oscillator equivalent current 326 and the conversion equivalent current 328. When the differential amplifier drive current 324 becomes large, the operation of the differential amplifier 52 becomes high speed. That is, even if the first original oscillation signal 310 and the second original oscillation signal 312 fluctuate at a higher oscillation frequency, since the differential amplifier driving current 324 becomes large, the operation of the differential amplifier 52 is also higher oscillation. According to the frequency, the amplitudes of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 become larger.

Further details will be described later in Embodiment 2, and since the differential amplifier drive current 324 is also provided with a conversion equivalent current 328, the first amplified oscillation signal 314 and the second amplified oscillation signal 316 Even if the amplitude becomes larger, the amplitudes of the first current oscillation signal 320 and the second current oscillation signal 322 also increase, regardless of the value of the conversion constant current 318.

2 shows the time variation of the first amplified oscillation signal 314 as an output signal of the differential amplifier 52. The solid line in the figure shows the case where the differential amplifier drive current 324 is large enough, and the dotted line in the figure shows the case where the differential amplifier drive current 324 is small. When the differential amplifier drive current 324 is large, the amplitude of the first amplified oscillation signal 314 because the operation of the differential amplifier 52 can sufficiently follow the fluctuation of the first oscillation signal 310 of a high oscillation frequency. Also grows. On the other hand, when the differential amplifier drive current 324 is small, since the operation of the differential amplifier 52 cannot sufficiently follow the fluctuation of the first original oscillation signal 310, the amplitude of the first amplified oscillation signal 314 is It becomes smaller. The same applies to the second amplified oscillation signal 316.

3 shows the output current converted from the voltage in the conversion amplifier circuit 54. The solid line in the figure shows the case where the amplitude of the 1st amplified oscillation signal 314 and the 2nd amplified oscillation signal 316 is large, and the dotted line in a figure shows the 1st amplified oscillation signal 314 and the 2nd amplified oscillation signal ( The case of 316) is small. The case where the amplitude of the 1st amplified oscillation signal 314 and the 2nd amplified oscillation signal 316 is small assumes the case where the conversion equivalent current 328 is not added to the differential amplifier drive current 324, for example. do. When the amplitude of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 is large, the switching of the first switch circuit 62 and the second switch circuit 64 becomes high speed, and the first current oscillation signal is sufficiently satisfied. Since it can convert into 320 and the 2nd current oscillation signal 322, the amplitude of the output current converted by the conversion amplifier circuit 54 also becomes large as a result. On the other hand, if the amplitude of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 is small, it cannot be sufficiently converted into the first current oscillation signal 320 and the second current oscillation signal 322, As a result, the amplitude of the output current converted by the conversion amplifier circuit 54 becomes small.

Here, the "amplitude of the output current" is defined by, for example, the sum of the maximum value of the magnitude of the sink current and the source current, the maximum value of the magnitude of the sink current, the maximum value of the magnitude of the source current, and the like. No distinction shall be made.

In the configuration of the high frequency oscillation circuit 100 according to the present embodiment, the voltage controlled oscillation circuit 50 and the differential amplifier 52 transmit a balance signal of voltage based on differential processing, and finally convert and amplify the balance signal. The circuit 54 converts the current signal into an unbalanced signal. Since the distortion component of the signal is also canceled between the balance signals by such a configuration, the distortion component of the signal is reduced, and as a result, the harmonic component of the electromagnetic interference (EMI) is reduced. Therefore, the high frequency oscillation circuit 100 can output a signal in which harmonic components are not unnecessarily included.

The operation of the high frequency oscillation circuit 100 according to the above configuration is as follows. Increasing the control voltage 306 also increases the oscillator drive current 308 and the oscillator equivalent current 326 through which the voltage controlled current source 58 flows. The signal oscillator circuit 60 outputs a first oscillation signal 310 and a second oscillation signal 312 having a higher oscillation frequency when the oscillator driving current 308 becomes large. In addition, as the oscillator equivalent current 326 increases, the differential amplifier drive current 324 flowing from the adder 56 also increases. As the differential amplifier drive current 324 becomes large, the differential amplifier 52 converts the first oscillation signal 310 and the second oscillation signal 312 of the higher oscillation frequency to the first amplified oscillation signal 314 of sufficiently large amplitude. ) And a second amplified oscillation signal 316, respectively.

The first switch circuit 62 and the second switch circuit 64 receive the first amplified oscillation signal 314 and the second amplified oscillation signal 316 based on the constant current 318 for conversion from the constant current source 70. The first current oscillation signal 320 and the second current oscillation signal 322 are respectively converted. The first current value converting amplifier circuit 66 and the second current value converting amplifier circuit 68 convert the values of the first current oscillation signal 320 and the second current oscillation signal 322, respectively, and further include a first switch. The switching of the circuit 62 and the second switch circuit 64 results in the final output current. Further, since the equivalent current 328 for conversion from the constant current source 70 flows to the differential amplifier 52 in addition to the differential amplifier drive current 324 regardless of the magnitude of the control voltage 306, the first switch The amplitudes of the first current oscillation signal 320 and the second current oscillation signal 322 converted by the circuit 62 and the second switch circuit 64 are closer to the values of the conversion constant current 318.

According to this embodiment, the current according to the oscillation frequency of the oscillation signal flows to the differential amplifier. Therefore, when the oscillation frequency is high, the amplitude of the output current can be increased, and when the oscillation frequency is low, the operation of low power consumption is performed. It can be realized. In addition, because the current flows in proportion to the current used to convert the voltage of the oscillation signal to the current, the switching characteristics in the amplifier become faster, and the oscillation signal can be amplified with a larger amplitude voltage. Therefore, the amplitude of the output current can be increased.

(Embodiment 2)

The second embodiment is the same high frequency oscillation circuit as in the first embodiment. In the first embodiment, the high frequency oscillation circuit is described by the functional block. In the second embodiment, the high frequency oscillation circuit is described by the circuit arrangement such as the FET.

4 shows a high frequency oscillation circuit 100 according to the second embodiment. In addition, in the figure, the same thing as the functional block and signal in FIG. 1 are represented with the same code | symbol.

The variable current source 72 allows current to vary in accordance with the control voltage 306. The transistors Tr1 to Tr3 constitute a current mirror circuit, and the oscillator equivalent current 326 and the oscillator driving current 308 flow from the transistors Tr2 and Tr3, respectively. As described above, the oscillator drive current 308, the oscillator equivalent current 326, and the currents from the variable current source 72 have a proportional relationship with each other.

The transistors Tr4 to Tr9 form a current mirror circuit, and the transistors Tr10 to Tr14 also form a current mirror circuit. These current mirror circuits allow the current according to the oscillator drive current 308 to be differentially configured by the first inverter 74, the second inverter 76, the third inverter 78, and the fourth inverter 80, respectively. Flows into the mold ring oscillator. In other words, when the oscillator drive current 308 increases, the current flowing through the ring oscillator increases, so that the oscillation frequencies of the first and second oscillation signals 310 and 312 output from the ring oscillator increase.

The transistors Tr15 to Tr18, the transistor Tr23, and the transistor Tr24 constitute the differential amplifier 52, and the first original oscillation signal 310 and the second original oscillation signal 312 are transistors (Tr15). The signals are applied to the gate terminals of the transistors Tr23 and Tr24, respectively, and differentially amplified. This differential amplification process aims at increasing the drive capability of the transistors Tr32 and Tr33 described later, similarly to the first embodiment. In addition, since the transistors Tr19 to Tr22, Tr25, and Tr26 also form the differential amplifier 52, the first original oscillation signal 310 and the second original oscillation signal 312 are provided. Is amplified in two stages and output as a first amplified oscillation signal 314 and a second amplified oscillation signal 316, respectively. In addition, the differential amplifier drive current 324 flowing to each differential amplifier 52 is mentioned later.

The transistors Tr41 and Tr40 constitute a current mirror circuit, and are equivalent to conversions having a proportional relationship with the constant constant current 318 for conversion and the constant constant current 318 from the variable current source 82. Current 328 flows.

The transistor Tr32 converts the first amplified oscillation signal 314 applied to the gate terminal into the first current oscillation signal 320. Since the transistor Tr32 is an n-channel type, when the value of the first amplified oscillation signal 314 increases, the value of the first current oscillation signal 320 also approaches the value of the constant current 318 for conversion. The transistor Tr33 performs the same operation as the transistor Tr32 and converts it into the second current oscillation signal 322. The transistors Tr34 and Tr35 form a current mirror circuit, and are converted to a first output current having a proportional relationship with the first current oscillation signal 320. In addition, the transistors Tr36 and Tr37, and the transistors Tr38 and Tr39 each constitute a current mirror circuit, each having a second output current having a proportional relationship with the second current oscillation signal 322. Convert. The first output current and the second output current become final output currents by switching between the transistors Tr32 and Tr33.

The transistor Tr27, the transistor Tr28, and the transistor Tr30 constitute a current mirror circuit, and the differential amplifier driving current 324 having a proportional relationship with the oscillator equivalent current 326 is the transistor Tr28 and the transistor Tr30. Flows from). As described above, when the oscillator equivalent current 326 increases, the differential amplifier drive current 324 also increases accordingly.

The reason why the current proportional to the conversion equivalent current 328 is added to the differential amplifier drive current 324 is as follows. In order to increase the amplitude of the final output current, it is necessary to increase the conversion constant current 318. However, when the gate-source voltage of the transistors Tr32 and Tr33 is low, the switching operation of the transistors Tr32 and Tr33 is delayed, so that the first current oscillation signal 320 and the second current oscillation are performed. The constant current 318 for conversion cannot be efficiently transferred to the amplitude of the signal 322. Therefore, the equivalent current 328 for conversion having a constant relationship with the constant current 318 for conversion is made to flow, and the current which flows from the current mirror circuit which consists of transistor Tr41, transistor Tr31, and transistor Tr29 is differential amplifier. Add to drive current 324.

As a result, since the differential amplifier drive current 324 flowing through the differential amplifier 52 becomes larger, the operating characteristics of the differential amplifier 52 become higher. Therefore, it is possible to follow the fluctuation of the first original oscillation signal 310 and the second original oscillation signal 312, and the amplitude of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 is sufficiently large. . As a result, the maximum value of the gate-source voltage of the transistors Tr32 and Tr33 is increased, so that the switching operation between the transistors Tr32 and Tr33 is faster, and the constant current for conversion is converted to the amplitude of the final output current. 318 can be delivered efficiently.

FIG. 2 shows the time change of the first amplified oscillation signal 314 or the second amplified oscillation signal 316 as an output signal of the differential amplifier 52, and FIG. 3 is converted from voltage in the conversion amplification circuit 54. Although output current is shown, since it is the same as Embodiment 1, these description is abbreviate | omitted here.

The operation of the high frequency oscillation circuit 100 according to the above configuration is as follows. When the control voltage 306 is increased, the oscillator equivalent current 326 through which the transistor Tr2 flows in the current mirror circuit and the oscillator drive current 308 through which the transistor Tr3 flows become large. When the oscillator drive current 308 becomes large, the first original oscillation signal 310 and the second outputted from the first inverter 74, the second inverter 76, the third inverter 78, and the fourth inverter 80. The oscillation frequency of the original oscillation signal 312 becomes high. In addition, when the oscillator equivalent current 326 increases, the differential amplifier drive current 324 which causes the transistors Tr28 and Tr30 in the current mirror circuit to flow also increases. When the differential amplifier drive current 324 becomes large, in the differential amplifier 52, the first oscillation signal 310 and the second oscillation signal 312 having a higher oscillation frequency are replaced with the first amplified oscillation signal having a sufficiently large amplitude ( 314 and the second amplified oscillation signal 316, respectively.

The transistors Tr32 and Tr33 remove the first amplified oscillation signal 314 and the second amplified oscillation signal 316 based on the conversion constant current 318 from the transistor Tr40 in the current mirror circuit. The first current oscillation signal 320 and the second current oscillation signal 322 are respectively converted. Transistor Tr35 in the current mirror circuit converts the value of the first current oscillation signal 320, and transistor Tr39 in another current mirror circuit converts the value of the second current oscillation signal 322. The converted current becomes the final output current according to the switching of the transistors Tr32 and Tr33. In addition, regardless of the magnitude of the control voltage 306, the transistor equivalent current 328 is added to the differential amplifier driving current 324 by the transistors Tr31 and Tr29, and therefore, the transistors Tr32 and The gate-source voltage of the transistor Tr33 also increases, and as a result, the amplitude of the first current oscillation signal 320 and the second current oscillation signal 322 becomes closer to the value of the constant current 318 for conversion.

According to the present embodiment, when the control voltage is increased, the oscillation frequency of the oscillation signal is increased and the transistor in the differential amplifier operates at high speed, so that the amplitude of the output current can be increased, while the oscillation frequency is low. The transistor can be operated at low power consumption. In addition, since a current proportional to the current used in the transistor for converting the voltage of the oscillation signal into a current flows through the transistor in the differential amplifier, the transistor in the differential amplifier operates at a high speed, so that the amplification of the oscillation signal is increased. The voltage of the oscillation signal can be efficiently converted into a current.

(Embodiment 3)

Embodiment 3 demonstrates the structure of the apparatus or LSI to which the high frequency oscillation circuit in Embodiment 1 or 2 is applied.

FIG. 5A shows the configuration of the optical pickup 200 in the application example of the high frequency oscillation circuit 100 according to the third embodiment. The optical pickup 200 includes a high frequency oscillation circuit 100, a semiconductor laser chip 102, a monitor photodiode 104, and a light reception photodiode 108. The optical pickup 200 reads or writes signals to a disc as a recording medium in an information recording and reproducing apparatus such as an optical disc apparatus or a magneto-optical disc apparatus.

The semiconductor laser chip 102 emits a laser beam in accordance with a current supplied from the high frequency oscillation circuit 100 described later. The high frequency oscillation circuit 100 supplies a current to the semiconductor laser chip 102 based on a control signal represented by a voltage from an APC (Automatic Power Control) circuit 106 described later.

The optical system 110 irradiates a laser beam emitted from the semiconductor laser chip 102 as a light spot on a disk of a recording medium (not shown), and guides the reflected light from the disk to the light receiving photodiode 108 described later.

The light receiving photodiode 108 converts the reflected light into a current signal. The current signal is also converted into a voltage signal. The monitor photodiode 104 converts a part of the laser beam emitted from the semiconductor laser chip 102 into a current signal. In addition, a part of a laser beam here means the laser beam radiate | emitted from the side in which the optical system 110 of the semiconductor laser chip 102 does not exist.

The APC circuit 106 controls the control signal to the high frequency oscillation circuit 100 so that the laser beam is always output at a constant power from the semiconductor laser chip 102 based on the current signal output from the monitor photodiode 104. Is output, that is, feedback control of the semiconductor laser chip 102 is performed. Here, the APC circuit 106 is provided for the following reasons. Although it is necessary to maintain the voltage signal level output by the optical pickup 200 at a predetermined level, the power of the laser beam output by the semiconductor laser chip 102 is sensitive to temperature changes at the same time as there is individual difference. Only by performing the same control over the chip 102, the power of the laser beam is not constant, and therefore, the output level of the voltage signal cannot be kept constant.

On the other hand, since the high frequency oscillation circuit 100 can increase the amplitude of the output current even at a high oscillation frequency as described in Embodiments 1 and 2, the semiconductor laser chip 102 can stably emit a laser beam.

FIG. 5B shows the configuration of the frequency conversion circuit 202 in the application example of the high frequency oscillation circuit 100 according to the third embodiment. The frequency conversion circuit 202 includes a high frequency oscillation circuit 100, a multiplication circuit 122, a bandpass filter (BPF) 124, and an amplifier 126. The frequency conversion circuit 202 converts the signal to be transmitted into a signal for transmission in the communication device. More specifically, in the radio transmitting apparatus, a baseband signal to be transmitted or an intermediate frequency signal obtained by frequency converting the baseband signal is frequency converted into a radio frequency signal.

The signal generator 120 generates a signal to be transmitted as a baseband signal and frequency converts the baseband signal to an intermediate frequency.

The high frequency oscillation circuit 100 inputs a voltage corresponding to a radio frequency used for transmission, and outputs a radio frequency signal.

The multiplication circuit 122 frequency-converts the signal of the intermediate frequency by the signal of the radio frequency. In addition, the BPF 124 reduces the influence of harmonics generated by the frequency conversion.

The amplifier 126 amplifies up to a predetermined power in order to transmit the output signal of the BPF 124 in the radio wave path.

Here, since the high frequency oscillation circuit 100 can output a large value of current even at a high oscillation frequency, as described in Embodiments 1 and 2, the semiconductor laser chip 102 can stably output a radio frequency signal. .

FIG. 5C shows the configuration of the PLL 204 in the application example of the high frequency oscillation circuit 100 according to the third embodiment. The PLL 204 includes a high frequency oscillation circuit 100, a phase comparator 150, a loop filter 152, and a divider 154.

The phase comparator 150 compares the phase and the frequency of the reference clock signal input from the outside and the reference clock signal input from the divider 154 and outputs a DC signal proportional to the difference. The loop filter 152 removes high frequency components of an input signal and outputs a control voltage. The high frequency oscillation circuit 100 outputs a clock signal having a frequency corresponding to the input control voltage. Here, a clock signal having a frequency N times the frequency of the reference clock signal is output. The output clock signal is divided at 1 / N by the divider 154 and input to the phase comparator 150 as a reference clock signal.

According to this embodiment, a high frequency oscillation circuit capable of increasing the amplitude of the output current even at a high oscillation frequency and realizing low power consumption at a low oscillation frequency can be applied to various devices and LSIs.

Moreover, correspondence of the structure which concerns on this invention and embodiment is illustrated. The " differential oscillation signal generating circuit " corresponds to the transistor Tr1, the transistor Tr3, and the signal oscillation circuit 60 in the variable current source 72 of the voltage controlled current source 58 and the current mirror circuit. The "differential amplifier" corresponds to the differential amplifier 52. The "conversion amplifier circuit" corresponds to the conversion amplifier circuit 54. The " frequency dependent adjusting circuit " includes transistors Tr1, transistor Tr2, and transistor Tr27, transistor Tr28, and transistor Tr28 in the current mirror circuit of the voltage controlled current source 58. It corresponds to (Tr30). The " differential ring oscillator " corresponds to the first inverter 74, the second inverter 76, the third inverter 78, and the fourth inverter 80 in the signal oscillation circuit 60. FIG. The "drive circuit" corresponds to the transistors Tr4 to Tr14 in the two current mirror circuits of the signal oscillation circuit 60.

The "differential oscillation signal generation circuit" corresponds to the transistor Tr1, the transistor Tr3, and the signal oscillation circuit 60 in the variable current source 72 of the voltage controlled current source 58 and the current mirror circuit. The "differential amplifier" corresponds to the differential amplifier 52. The "conversion amplifier circuit" corresponds to the conversion amplifier circuit 54. The "setting circuit" corresponds to the constant current source 70. The "output dependent regulating circuit" corresponds to the transistors Tr41, Tr31, and Tr29 in the current mirror circuit of the constant current source 70 and the adder 56.

In the above, this invention was demonstrated based on embodiment. This embodiment is an illustration, It will be understood by those skilled in the art that various modifications are possible for each of these component and the combination of each processing process, and such a modification is also in the scope of the present invention.

In Embodiment 2, the differential amplifier 52 is comprised by two differential amplifiers. However, the present invention is not limited thereto, and may be constituted by, for example, one differential amplifier or three or more differential amplifiers. According to this modification, the amplitudes of the first amplified oscillation signal 314 and the second amplified oscillation signal 316 can be changed. That is, the number of differential amplifiers according to the values required for the first amplified oscillation signal 314 and the second amplified oscillation signal 316 output from the differential amplifier 52 may be provided.

While the invention has been described in terms of exemplary embodiments, it should be understood that many changes and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the appended claims.

According to the present invention, the operating characteristics of the differential amplifier can be adjusted according to the oscillation frequency of the oscillation signal. Therefore, when the oscillation frequency is high, the differential amplifier operates at a higher speed, and thus it is possible to output an oscillation signal having a high oscillation frequency. In addition, since the differential signal is processed, the distortion component of the signal is canceled even at a high oscillation frequency, and the distortion component of the signal is reduced.

In addition, according to the present invention, the operation characteristics of the differential amplifier can be adjusted according to the setting for converting the voltage of the oscillation signal into a current, so that the current of the oscillation signal is increased by the high speed operation of the differential amplifier, for example, and outputs the output. It is possible.

1 is a diagram showing a high frequency oscillation circuit according to Embodiment 1,

2 is a view showing an output signal of the amplifier of FIG.

3 is a diagram illustrating an output current converted from a voltage in the conversion amplifier circuit of FIG. 1;

4 is a diagram showing a high frequency oscillation circuit according to Embodiment 2;

5A to 5C are diagrams showing an application example of the high frequency oscillation circuit according to the third embodiment.

<Explanation of symbols for the main parts of the drawings>

50: voltage controlled oscillation circuit 52: differential amplifier

54 conversion amplifier circuit 56 adder

58: voltage controlled current source 60: signal oscillation circuit

62: first switch circuit 64: second switch circuit

66: first current value conversion amplifier circuit 68: second current value conversion amplifier circuit

70: constant current source 100: high frequency oscillation circuit

Claims (5)

A differential oscillation signal generation circuit capable of setting an oscillation frequency of an oscillation signal and outputting the oscillation signal having an oscillation frequency set as a differential signal; A differential amplifier for differentially amplifying the oscillation signal output as the differential signal; A conversion amplifier circuit for converting and amplifying the voltage of the differentially amplified oscillation signal into a current; And And a frequency dependent adjusting circuit for adjusting an operating characteristic of the differential amplifier according to the setting contents of the differential oscillating signal generating circuit. The oscillation circuit according to claim 1, wherein in the differential oscillation signal generation circuit, when the oscillation frequency of the oscillation signal is set high, the frequency dependent adjustment circuit increases the operation speed of the differential amplifier. The circuit of claim 1, wherein the differential oscillation signal generating circuit comprises: Differential ring oscillators; And A driving circuit for driving a driving current according to the setting contents with respect to the differential ring oscillator, And the frequency dependent adjusting circuit causes a current according to the driving current to flow through the differential amplifier to operate the differential amplifier. A differential oscillation signal generation circuit for outputting a predetermined oscillation signal as a differential signal; A differential amplifier for differentially amplifying the oscillation signal output as the differential signal; A conversion amplifier circuit for converting and amplifying the voltage of the differentially amplified oscillation signal into a current; A setting circuit for setting conversion characteristics of the conversion amplifier circuit; And And an output dependent adjustment circuit for adjusting an operating characteristic of the differential amplifier in accordance with the setting contents of the setting circuit. The oscillation circuit according to claim 4, wherein in the setting circuit, when the current for converting the voltage of the oscillation signal to a large current is set, the output dependent adjustment circuit increases the operation speed of the differential amplifier. .