JP2012235208A - Crystal oscillator - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a crystal oscillator, performing intermittent operation to each output signal, to suppress power consumption.SOLUTION: The crystal oscillator includes: a power voltage application terminal 111 to which a power voltage is applied; a temperature compensation-type crystal oscillator circuit unit 110 connected to the power voltage application terminal; a first buffer amplifier unit 120 connected to the temperature compensation-type crystal oscillator circuit unit and the power voltage application terminal; a first signal output terminal 121 connected to the first buffer unit and having a signal input from the first buffer unit; a first E/D terminal 122 connected to the first buffer amplifier unit and having a signal input enabling controlling to operate or suspend the first buffer amplifier unit; a second buffer amplifier unit 130 connected to the temperature compensation-type crystal oscillator circuit unit and the first buffer amplifier unit; a second output terminal 131 connected to the second buffer amplifier unit and having a signal input from the second buffer amplifier unit; and a second E/D terminal 132 connected to the second buffer amplifier unit and having a signal input enabling controlling to operate or suspend the second buffer amplifier unit.

Description

  The present invention relates to a crystal oscillator used in a mobile communication device, and more particularly to a crystal oscillator that outputs two or more signals.

A mobile communication device such as a mobile phone needs a crystal oscillator that generates a reference signal necessary for transmitting and receiving signals.
In mobile communication devices, microcomputers (CPUs) are used in mobile communication devices due to the recent multi-functionalization of mobile communication devices, and at the same time, a crystal oscillator that generates clock signals necessary for the CPU is required. ing.

  For this reason, in a mobile communication device, with the recent miniaturization of mobile communication devices, for example, a crystal oscillator that can output two signals of a reference signal and a clock signal is used.

  Such a crystal oscillator 300 includes, for example, a temperature compensated crystal oscillation circuit unit 310 and a buffer amplification unit 320 as shown in FIG.

The temperature-compensated crystal oscillation circuit unit 310 is connected to the power supply voltage application terminal 311 and enters the oscillation state when a power supply voltage is applied to the power supply voltage application terminal 311.
The temperature-compensated crystal oscillation circuit unit 310 is connected to the buffer amplifier 320 and the second output terminal 331, and outputs a signal to the buffer amplifier 320 and the first output terminal 331.

  The buffer amplifier 320 is connected to the power supply voltage application terminal 311 and the second output terminal 331, operates when a power supply voltage is applied to the power supply voltage application terminal 311, and is input from the temperature compensated crystal oscillation circuit unit 310. The converted signal is converted and a signal is output to the first output terminal 321.

  Therefore, in such a crystal oscillator 300, when a power supply voltage is applied to the power supply voltage application terminal 311, the buffer amplifier 320 operates while the temperature compensated crystal oscillation circuit section 310 is in an oscillation state, and the first output terminal 321 and the second output terminal 331 are configured to output different signals from each other (see, for example, Patent Document 1).

As another example of the crystal oscillator having two output signals, another buffer amplification unit 430 is provided between the temperature compensated crystal oscillation circuit unit 310 and the second output terminal 331 as shown in FIG. There is a crystal oscillator 400.
Here, the buffer amplifier 320 provided between the temperature compensated crystal oscillation circuit 310 and the first output terminal 321 is used as the first buffer amplifier, and the temperature compensated crystal oscillator 310 and the second Another buffer amplification unit 430 provided between the output terminal 331 and the output terminal 331 is a second buffer amplification unit.

  As described above, the temperature-compensated crystal oscillation circuit unit 310 is connected to the power supply voltage application terminal 311 and operates when the power supply voltage is applied to the power supply voltage application terminal 311 and enters an oscillation state. At this time, a signal is output from the temperature compensated crystal oscillation circuit unit 310 to the first buffer amplification unit and a second buffer amplification unit described later.

As described above, the first buffer amplification unit is connected to the power supply voltage application terminal 311 and is configured to operate when a power supply voltage is applied to the power supply voltage application terminal 311.
The first buffer amplifier outputs a signal to the first output terminal 321 when a signal is input from the temperature-compensated crystal oscillation circuit unit 310 when a power supply voltage is applied to the power supply voltage application terminal 311. It is the composition to do.

As shown in FIG. 4, the second buffer amplification unit is provided between the temperature-compensated crystal oscillation circuit unit 310 and the second output terminal 331 while being connected to the first buffer amplification unit.
Further, when the power supply voltage is applied to the power supply voltage application terminal 311, the second buffer amplification unit operates by applying a power supply voltage corresponding to the power supply voltage of the second buffer amplification unit from the first buffer amplification unit. It has a configuration. Therefore, the second buffer amplification unit is configured to operate when a power supply voltage is applied to the power supply voltage application terminal 311.
In addition, when the power supply voltage is applied to the power supply voltage application terminal 311, the second buffer amplification unit outputs a signal to the second output terminal 331 when a signal is input from the temperature compensated crystal oscillation circuit unit 310. It has a configuration.

Therefore, in such a crystal oscillator 400, as shown in FIG. 4, a buffer amplifier is provided between the temperature compensated crystal oscillation circuit 310 and each signal output terminal.
Further, such a crystal oscillator 400 has a circuit configuration in which when the power supply voltage is applied to the power supply voltage application terminal 311, the temperature compensated crystal oscillation circuit unit 310 and all the buffer amplification units operate.

In general, crystal oscillators used in mobile communication devices such as mobile phones are intermittently operated so that signals are not output from the respective output terminals when output signals are unnecessary in order to reduce power consumption. ing.
In the two crystal oscillators described above, the power supply voltage is not applied to the power supply voltage application terminal 311 so that the crystal oscillation circuit unit and the buffer amplification unit are stopped so that no signal is output from the output terminal. Therefore, in the above-described two crystal oscillators, intermittent operation is performed by setting the power supply voltage to the power supply voltage application terminal 311 or not applying it.

  JP 2004-007036 A

However, since the conventional crystal oscillator performs an intermittent operation by switching to a state where the power supply voltage is applied to the power supply voltage application terminal or not, so that there are two or more signals to be output, Intermittent operation cannot be performed on this signal.
For this reason, when one of the signals to be output is necessary, the conventional crystal oscillator has to apply the power supply voltage and oscillate the temperature compensated crystal oscillation circuit unit while continuing to operate all the buffer amplification units. This consumes a lot of power.

  An object of the present invention is to provide a crystal oscillator capable of performing intermittent operation on each output signal and suppressing power consumption.

In order to solve the above problems, a power supply voltage application terminal to which a power supply voltage is applied, a temperature compensated crystal oscillation circuit section connected to the power supply voltage application terminal and applied with a power supply voltage from the power supply voltage application terminal, and the power supply While being connected to a voltage application terminal and applying a power supply voltage from the power supply voltage application terminal,
A first buffer amplifier connected to the temperature-compensated crystal oscillator circuit unit and receiving a signal from the temperature-compensated crystal oscillator circuit unit; and a first buffer amplifier unit connected to the first buffer amplifier unit. A first E / D terminal to which a signal that can be controlled to operate or stop the unit is input;
A first output terminal to which a signal output from the first buffer amplifying unit is connected when the first buffer amplifying unit is operating and connected to the first buffer amplifying unit; A second buffer amplifier connected to the application terminal and connected to the temperature-compensated crystal oscillation circuit unit and receiving a signal from the temperature-compensated crystal oscillation circuit unit while applying a power supply voltage from the power supply voltage application terminal; ,
A second E / D terminal to which a signal that can be controlled to operate or stop the second buffer amplifier is input; and the second buffer amplifier connected to the second buffer amplifier A second output terminal to which a signal output from the second buffer amplification unit is input when is operating,
It is characterized by having.

In order to solve the above problem, an OR circuit unit is provided in which a signal different from a signal input from two signal input terminals is output from the signal output terminal, and one of the signal input terminals is the first E / D. A signal input from the first E / D terminal connected to a terminal, the other signal input terminal connected to the second E / D terminal and a signal input from the second E / D terminal;
The other signal input terminal is connected to a power supply voltage application terminal, and a signal for stopping the first buffer amplifying unit is input from the first E / D terminal while being input from the second E / D terminal. When a signal for stopping the second buffer amplification unit is input, the oscillation state of the temperature compensated crystal oscillation circuit unit is stopped.

According to such a crystal oscillator, when a power supply voltage is applied to the power supply voltage application terminal, the power supply voltage is applied to the first buffer amplification unit and the second buffer amplification unit while the temperature compensated crystal oscillation circuit unit is in an oscillation state. The first buffer amplification unit can be stopped by a signal input to the first E / D terminal in an applied state,
Since the second buffer amplification unit can be stopped by a signal input from the second E / D terminal, the output from the first E / D terminal to the first output terminal can be performed. The output from the second E / D terminal to the second output terminal can be controlled.
Therefore, according to such a crystal oscillator, when there are two output signals, it is possible to perform an intermittent operation on each output signal, and all the buffer amplifiers as in the conventional crystal oscillator Therefore, the power consumption can be suppressed as compared with the conventional crystal oscillator.

Further, according to such a crystal oscillator, a signal for stopping the first buffer amplification unit is input from the first E / D terminal, and the second buffer amplification unit is stopped from the second E / D terminal. When the signal is input, the oscillation state of the temperature-compensated crystal oscillation circuit is stopped, so the signal output from the first output terminal and the signal output from the second output terminal are not required ,
The oscillation state of the temperature compensated crystal oscillation circuit unit can be stopped.
Therefore, according to such a crystal oscillator, an intermittent operation can be performed for each output signal, and when all the output signals are unnecessary, the oscillation state of the temperature compensated crystal oscillation circuit unit is stopped. Power consumption can be further reduced.

It is a block diagram showing an example of a crystal oscillator concerning a first embodiment of the present invention. It is the block diagram which showed an example of the crystal oscillator which concerns on 2nd embodiment of this invention. It is the block diagram which showed an example of the conventional crystal oscillator. It is the block diagram which showed another example of the conventional crystal oscillator.

  Next, the best mode for carrying out the present invention will be described. In each drawing, the state of each component is exaggerated for easy understanding.

(First embodiment)
The crystal oscillator according to the first embodiment of the present invention is configured to output a plurality of signals, for example, configured to output two signals.
The crystal oscillator 100 according to the first embodiment of the present invention includes, for example, a power supply voltage application terminal 111, a temperature compensated crystal oscillation circuit unit 110, a first buffer amplification unit 120, and a first buffer amplification unit, as shown in FIG. One output terminal 121, a first E / D terminal 122, a second buffer amplifier 130, a second output terminal 131, and a second E / D terminal 132 are provided.

The power supply voltage application terminal 111 is a terminal to which a power supply voltage is applied from an external power supply circuit unit (not shown).
Further, as shown in FIG. 1, the power supply voltage application terminal 111 is connected to a temperature compensated crystal oscillation circuit unit 110 described later and a first buffer amplification unit 120 described later.

The temperature-compensated crystal oscillation circuit unit 110 is connected to the power supply voltage application terminal 111 as described above. When the power supply voltage is applied to the power supply voltage application terminal 111, the temperature compensation crystal oscillation circuit unit 110 operates and enters an oscillation state.
The temperature compensated crystal oscillation circuit unit 110 is configured to output a signal from the signal output terminal of the temperature compensated crystal oscillation circuit unit 110 when the temperature compensated crystal oscillation circuit unit 110 is in an oscillation state. .

The first buffer amplification unit 120 is connected to the power supply voltage application terminal 111, and when the power supply voltage is applied to the power supply voltage application terminal 111, the power supply voltage is applied from the power supply voltage application terminal 111.
The first buffer amplifier 120 is connected to a signal output terminal of the temperature compensated crystal oscillation circuit unit 110 and receives a signal output from the signal output terminal of the temperature compensated crystal oscillation circuit unit 110.

The first E / D terminal 122 is connected to the first buffer amplification unit 120.
The first E / D terminal is connected to an external first signal supply circuit unit (not shown), and is a terminal to which a signal, for example, a voltage signal is input.
The first E / D terminal 122 can be controlled to operate or stop the first buffer amplification unit 120 when the power supply voltage is applied to the power supply voltage application terminal 111. A signal is input.

The first output terminal 121 is connected to the first buffer amplifier 120, and when the first buffer amplifier 120 is operating, the signal output from the first buffer amplifier 120 is input. Terminal. In other words, the first output terminal 121 is a terminal that outputs a signal from the buffer amplifier 120 when the first buffer amplifier 120 is operating.
Therefore, when a predetermined signal is input from the first E / D terminal to the first output terminal 121 and the first buffer amplification unit 120 is stopped, a signal is output from the first buffer amplification unit 120. Not.

The second buffer amplification unit 130 is connected to, for example, the first buffer amplification unit 120 connected to the power supply voltage application terminal 111.
The second buffer amplifying unit 130 supplies power to the second buffer amplifying unit 130 by an internal wiring (not shown) of the first buffer amplifying unit 120 when a power supply voltage is applied to the power supply voltage application terminal 111. The voltage is applied.
Even when the first buffer amplification unit 120 is stopped, when the power supply voltage is applied to the power supply voltage application terminal 111, the power supply voltage is applied to the second buffer amplification unit 130. ing.
That is, the second buffer amplification unit 130 can be regarded as having a configuration in which the power supply voltage is applied from the power supply voltage application terminal 111 connected to the power supply voltage application terminal 111.

  The second buffer amplifier 130 is connected to a signal output terminal of the temperature compensated crystal oscillation circuit unit 110 and receives a signal output from the signal output terminal of the temperature compensated crystal oscillation circuit unit 110.

The second E / D terminal 132 is connected to the second buffer amplification unit 130.
The second E / D terminal 132 is connected to an external second signal supply circuit unit (not shown), and is a terminal to which a signal, for example, a voltage signal is input.
In addition, the second E / D terminal 132 can be controlled to operate or stop the second buffer amplifier 230 when the power supply voltage is applied to the power supply voltage application terminal 111. A signal is input.

The second output terminal 131 is connected to the second buffer amplifier 130, and when the second buffer amplifier 130 is operating, the signal output from the second buffer amplifier 130 is input. Terminal. In other words, the second output terminal 131 is a terminal for outputting a signal from the second buffer amplifier 130 when the second buffer amplifier 130 is operating.
Therefore, when a predetermined signal is input to the second output terminal 131 from the second E / D terminal and the second buffer amplifier 130 is stopped, a signal is output from the second buffer amplifier 130. Not.

  Therefore, in the crystal oscillator 100 according to the first embodiment of the present invention, when the power supply voltage is applied to the power supply voltage application terminal 111, the temperature compensated crystal oscillation circuit unit 110 enters the oscillation state, and the first buffer amplification unit 120 is activated. The power supply voltage is applied to the second buffer amplifier 130.

While a predetermined signal for stopping the first buffer amplification unit 110 is input from the first E / D terminal 122, a predetermined signal for stopping the second buffer amplification unit 110 from the second E / D terminal 122 is received. In the case of the input, in the crystal oscillator 100 according to the first embodiment of the present invention, when the power supply voltage is applied to the power supply voltage application terminal 111, only the temperature compensated crystal oscillation circuit unit 110 operates.
The first buffer amplifier 120 and the second buffer amplifier 130 are stopped, and no signal is output from the first output terminal 121 and the second output terminal 131.

In addition, a predetermined signal for stopping the first buffer amplification unit 110 from the first E / D terminal 122 is input, and a predetermined signal for operating the second buffer amplification unit 110 from the second E / D terminal 122 is input. When other signals are input, the crystal oscillator 100 according to the first embodiment of the present invention has the temperature compensated crystal oscillation circuit unit 110 and the second one when the power supply voltage is applied to the power supply voltage application terminal 111. The buffer amplification unit 130 of the
The first buffer amplification unit 110 is stopped, and no signal is output from the first output terminal 121, and a signal is output only from the second output terminal 131. At this time, the power supply voltage is applied to the second buffer amplification unit 130 from the power supply voltage application terminal 111 through the internal wiring of the stopped first buffer amplification unit 120.

Further, the second buffer amplifier 130 is stopped from the second E / D terminal 132 while another predetermined signal for operating the first buffer amplifier 120 is input from the first E / D terminal 122. When a predetermined signal is input, the crystal oscillator 100 according to the first embodiment of the present invention has the temperature-compensated crystal oscillation circuit unit 110 and the first circuit when the power supply voltage is applied to the power supply voltage application terminal 111. The buffer amplification unit 120 of the
The second buffer amplifier 130 is stopped, a signal is output from the first output terminal 121, and no signal is output from the second output terminal 131.

Also, the second buffer amplifier 130 is operated from the second E / D terminal 132 while a predetermined other signal for operating the first buffer amplifier 120 is input from the first E / D terminal 122. When a predetermined other signal is input, the crystal oscillator 100 according to the first embodiment of the present invention has the temperature compensated crystal oscillation circuit unit 110 when the power supply voltage is applied to the power supply voltage application terminal 111. The first buffer amplification unit 120 and the second buffer amplification unit 130 operate,
A signal is output from the first output terminal 121 and the second output terminal 131.

Therefore, the crystal oscillator 100 according to the first embodiment of the present invention can control the signal output from the first output terminal 121 by the signal input to the first E / D terminal 122. The signal output from one output terminal 121 can be intermittently operated.
Further, the crystal oscillator 100 according to the first embodiment of the present invention can control the signal output from the second output terminal 131 by the signal input to the second E / D terminal 132. The configuration is such that an intermittent operation can be performed on a signal output from the second output terminal 131.

Further, the crystal oscillator 100 according to the first embodiment of the present invention performs an intermittent operation on a signal output from the first output terminal 121 by a signal input from the first E / D terminal 122, Since the signal inputted from the second E / D terminal 132 can be intermittently operated with respect to the signal outputted from the second output terminal 131, the signal is outputted from the first output terminal 121. And the signal output from the second output terminal 131,
Each can perform intermittent operation independently.

According to the crystal oscillator 100 according to the first embodiment of the present invention, when the power supply voltage is applied to the power supply voltage application terminal 111, the temperature compensation type crystal oscillation circuit unit 110 is in the oscillation state and the first buffer is applied. The power supply voltage is applied to the amplification unit 120 and the second buffer amplification unit 130, and the first buffer amplification unit 120 can be stopped by a signal input from the first E / D terminal 122,
Since the circuit configuration is such that the second buffer amplifying unit 130 can be stopped by a signal input from the second E / D terminal 132, the first signal is input to the first E / D terminal 122. The output to the output terminal 121 can be controlled, and the output to the second output terminal 131 can be controlled by a signal input to the second E / D terminal 132.
For this reason, according to the crystal oscillator 100 according to the first embodiment of the present invention, when two output signals are provided, intermittent operation can be performed for each output signal. Since it is not necessary to operate all the buffer amplifiers 120 and 130 as in the case of the crystal oscillator, power consumption can be suppressed as compared with the conventional crystal oscillator.

(Second embodiment)
In the crystal oscillator 200 according to the second embodiment of the present invention, as shown in FIG. 2, the signals inputted to the first E / D terminal 122 and the second E / D terminal 132 are inputted as they are, and the power supply voltage This is different from the first embodiment in that an OR circuit unit configured to output a signal to the application terminal 111 is provided.

The OR circuit unit 240 includes a signal input terminal (not shown) and a signal output terminal (not shown).
The OR circuit unit 240 is configured such that a signal output from the signal output terminal of the OR circuit unit 240 is selected by a signal input from the signal input terminal of the OR circuit unit 240.

Two signal input terminals of the OR circuit unit 240 are provided.
As shown in FIG. 2, one signal input terminal is connected to the first E / D terminal 122. When a signal is input to the first E / D terminal 122, the first E / D terminal 122 is directly connected. The signal input to the D terminal 122 is input.
As shown in FIG. 2, the other signal input terminal is connected to the second E / D terminal 132. When a signal is input to the second E / D terminal 132, the second E / D terminal 132 is used as it is. The signal input to the D terminal 132 is input.

The signal output terminal of the OR circuit unit 240 is connected to the power supply voltage application terminal 111 as shown in FIG.
Further, different signals are output from the signal output terminal of the OR circuit unit 240 depending on the combination of the signal input to the first E / D terminal 122 and the signal input to the second E / D terminal 132.

  While the predetermined signal is input to the first E / D terminal 122 so as to stop the first buffer amplification unit 120, the predetermined signal is input to the second E / D so as to stop the second buffer amplification unit 130. When input to the D terminal 132, the OR circuit unit 120 enters a state in which the power supply voltage is not applied to the power supply voltage application terminal 111, and the oscillation is stopped without applying the power supply voltage to the temperature compensated crystal oscillator 110. ing.

  In addition, a predetermined signal is input to the first E / D terminal 122 so as to stop the first buffer amplifying unit 120, while a predetermined other signal is input so as to operate the second buffer amplifying unit 130. When input to the second E / D terminal 132, the OR circuit unit 120 is in a state in which the power supply voltage is applied to the power supply voltage application terminal 111, and the temperature compensation type crystal oscillator 110 is in the oscillation state and the first buffer is applied. The amplifying unit 120 is stopped and the second buffer amplifying unit 130 is operated.

  In addition, a predetermined other signal is input to the first E / D terminal 122 so as to operate the first buffer amplifying unit 120, while the predetermined signal is input to stop the second buffer amplifying unit 130. When input to the second E / D terminal 132, the OR circuit unit 120 is in a state in which the power supply voltage is applied to the power supply voltage application terminal 111, and the temperature compensation type crystal oscillator 110 is in the oscillation state and the first buffer is applied. The amplification unit 120 operates and the second buffer amplification unit 130 is stopped.

  In addition, a predetermined other signal is input to the first E / D terminal 122 so as to operate the first buffer amplifying unit 120, and a predetermined other signal is set so as to stop the second buffer amplifying unit 130. Is input to the second E / D terminal 132, the OR circuit unit 120 is in a state where a power supply voltage is applied to the power supply voltage application terminal 111, and the temperature compensated crystal oscillator 110 is in an oscillation state, while One buffer amplification unit 120 and the second buffer amplification unit 130 are configured to operate.

  Therefore, the OR circuit unit 240 receives a signal for stopping the first buffer amplification unit 120 from the first E / D terminal 122, and the second buffer amplification unit 132 from the second E / D terminal 132. When a signal for stopping the operation is input, the power supply voltage application terminal 111 can be in a state where no power supply voltage is applied, and the oscillation state of the temperature compensated crystal oscillation circuit unit 110 can be stopped. ing.

In the crystal oscillator 200 according to the second embodiment of the present invention, when the power supply voltage is applied to the power supply voltage application terminal 111, the temperature-compensated crystal oscillation circuit unit 110 is in the oscillation state and the first buffer amplification unit 120 and the second buffer amplifying unit 130 are applied with a power supply voltage, and the first buffer amplifying unit 120 can be stopped by a signal input from the first E / D terminal 122,
Since the circuit configuration is such that the second buffer amplifying unit 130 can be stopped by a signal input from the second E / D terminal 132, the same effects as those of the first embodiment can be obtained.

In addition, according to the crystal oscillator 200 according to the second embodiment of the present invention, a signal for stopping the first buffer amplifying unit 120 is input from the first E / D terminal 122 and the second E When the signal for stopping the second buffer amplification unit 130 is input from the / D terminal 132, the oscillation state of the temperature compensated crystal oscillation circuit unit 200 is stopped. Signal output from the second output terminal 131 is unnecessary,
The oscillation state of the temperature compensated crystal oscillation circuit unit 110 can be stopped.
Therefore, according to the crystal oscillator 200 according to the second embodiment of the present invention, intermittent operation can be performed on each output signal, and when all output signals are unnecessary, the temperature compensation type Since the oscillation state of the crystal oscillation circuit unit 110 can be stopped, power consumption can be further suppressed.

100, 200, 300, 400 Crystal oscillator 110, 310 Temperature compensation type crystal oscillation circuit unit 111, 311 Power supply voltage application terminal 120 First buffer amplification unit 121, 321 First signal output terminal 122 First E / D terminal 130 2nd buffer amplification part 131,331 1st signal output terminal 132 2nd E / D terminal 240 OR circuit part 320,430 Buffer amplification part

Claims (2)

A power supply voltage application terminal to which a power supply voltage is applied;
A temperature compensated crystal oscillation circuit unit connected to the power supply voltage application terminal and applied with a power supply voltage from the power supply voltage application terminal;
A first buffer connected to the power supply voltage application terminal and receiving a signal from the temperature compensation crystal oscillation circuit section connected to the temperature compensation crystal oscillation circuit section while applying a power supply voltage from the power supply voltage application terminal An amplification unit;
A first E / D terminal connected to the first buffer amplifying unit and receiving a signal that can be controlled to operate or stop the first buffer amplifying unit;
A first output terminal to which a signal output from the first buffer amplification unit is input when the first buffer amplification unit is connected to the first buffer amplification unit;
A second buffer connected to the power supply voltage application terminal and applied with a power supply voltage from the power supply voltage application terminal, and connected to the temperature compensated crystal oscillation circuit section and inputted with a signal from the temperature compensated crystal oscillation circuit section An amplification unit;
A second E / D terminal to which a signal that can be controlled to operate or stop the second buffer amplification unit is input;
A second output terminal to which a signal output from the second buffer amplification unit is connected when the second buffer amplification unit is connected to the second buffer amplification unit;
A crystal oscillator characterized by comprising: The crystal oscillator according to claim 1, wherein
An OR circuit unit is provided in which different signals are output from the signal output terminal depending on the signals input from the two signal input terminals,
One signal input terminal is connected to the first E / D terminal and a signal is input from the first E / D terminal,
The other signal input terminal is connected to the second E / D terminal, and a signal is input from the second E / D terminal,
The other signal input terminal is connected to a power supply voltage application terminal;
When a signal for stopping the second buffer amplification unit is input from the second E / D terminal while a signal for stopping the first buffer amplification unit is input from the first E / D terminal,
A crystal oscillator characterized in that the oscillation state of the temperature compensated crystal oscillation circuit section is stopped.

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