JPH021006A - Microcomputer - Google Patents

Abstract

PURPOSE:To reduce the power consumption from the time of the stand-by mode by controlling connection or disconnection of feedback resistances of all oscillating circuits in a microcomputer incorporating plural oscillating circuits. CONSTITUTION:When an oscillating circuit for a high frequency will be used, a connection control signal 15 is set to the low level to disconnect a feedback resistance 14 from terminals 16 and 17. Consequently, a current path passing the resistance 14 is eliminated when the terminal 16 is set to the low level; and if the oscillating circuit for the high frequency is stopped in the stand-by mode, the power consumption of the whole of the microcomputer is about zero. Meanwhile, when the microcomputer will be operated in a low-power consumption state, a connection control signal 10 is set to the low level to disconnect the current path of a feedback resistance 9, and the signal 15 is set to the high level to connect a crystal oscillator for a low frequency to terminals 16 and 17 and an oscillation signal is obtained, thereby using it as the system clock of the microcomputer.

Description

[Detailed Description of the Invention] [Industrial Application Field] The present invention relates to a microcomputer constructed of complementary metal oxide film semiconductors and having a plurality of built-in oscillation circuits. Related to lower power consumption by reducing flowing current.

[Conventional technology]

Conventionally, there are microcomputers that have built-in multiple oscillation circuits of this type, such as those that have built-in 4MHz crystal oscillator oscillation circuits and 32KHz crystal oscillator oscillation circuits, allowing microcomputers to process instructions at high speed. If you want to execute the command, use the 4MHz oscillation signal as the system clock and process the instructions while keeping the power consumption of the microcomputer low.If you want to execute the command, you can stop the 4MHz oscillation and use the 32KHz oscillation signal as the system clock. is common.

[Problem to be solved by the invention]

The above-mentioned conventional microcomputer with a plurality of built-in oscillation circuits has a control circuit for stopping the oscillation of the 4 MHz high-frequency crystal oscillator oscillation circuit and reducing the current flowing through the oscillation circuit. However, a control circuit for stopping oscillation is not added to the 32 KHz low frequency crystal oscillator oscillation circuit. Therefore, even when an oscillation circuit for a low-frequency crystal oscillator is not used, there is a drawback that the power consumed by the oscillation circuit cannot be reduced.

In particular, this drawback is that the microcomputer's oscillation and system clock generation are stopped to reduce power consumption.
This becomes noticeable in so-called standby mode. That is,
Even in standby mode, current flows only in the oscillation circuit for the low-frequency crystal oscillator in the microcomputer, and the current consumption in other parts is mostly OA (amperes). It will be consumed only in the oscillator circuit.

[Differences between the invention and the prior art]

While the above-mentioned conventional microcomputer with a plurality of built-in oscillation circuits cannot reduce the current flowing to the oscillation circuit for a low-frequency crystal oscillator, the present invention can reduce the current consumed by all the built-in oscillation circuits. There is a difference.

[Means to solve the problem]

A microcomputer incorporating a plurality of oscillation circuits according to the present invention has a plurality of oscillation circuits all connected to an inverter circuit, a feedback resistor connected in parallel with the inverter circuit, and a connection control circuit that controls whether or not to connect the feedback resistor. It is characterized by being composed of.

〔Example〕

The present invention will be explained with reference to the drawings.

First, FIG. 2 shows the basic configuration of an oscillation circuit for a crystal oscillator. A crystal oscillator l is connected in parallel to terminals 2 and 3,
Further, the terminals 2 and 3 are grounded via capacitors 4 and 5. On the other hand, the oscillation circuit inside the microcomputer is at terminal 2.
, 3 are connected in parallel with an inverter circuit 6 and a feedback resistor. The oscillation signal is obtained as the output of the inverter circuit 6 and is used as a system clock that is the basis of the operation of the microcomputer.

Next, FIG. 1 shows an embodiment of the present invention in which a plurality of (here, two) oscillation circuits for crystal oscillators are built-in.

The inverter circuit 8 and the feedback resistor 9 are, for example, an oscillation circuit for a high frequency crystal oscillator, and the feedback resistor 9 is connected to terminals 11 and 12 when the connection control signal 10 is at a high level, and is disconnected when it is at a low level.

The inverter circuit 13 and the feedback resistor 14 are, for example, an oscillation circuit for a low frequency crystal oscillator, and the feedback resistor 14 is a second
When the connection control signal 15 is at high level, the terminals 16 and 17
When it is at low level, it is disconnected from terminals 16 and 17.

The operation of the present invention will be described in detail below.

First, since the microcomputer executes command processing at high speed, when using a high frequency oscillation circuit, the connection control signal 15 of the tube 2 is set to a low level, and the terminals 16 and 17 are set to low level.
The feedback resistor 14 is separated from the Therefore, terminal 1
6 is grounded to a low level, for example, there will be no current path flowing through the feedback resistor 14, and if the high frequency oscillation circuit is stopped in standby mode (the first connection control signal 10 is at a low level), the microamplifier The user's system clock stops and the power consumption of the entire microcomputer drops to OW (watts). If the second connection control signal 15 is at a high level at this time (corresponding to the conventional example), an inverted logic will appear at the terminals 16 and 17, so a potential difference will occur between both ends of the feedback resistor 14. Current flows.

On the other hand, when operating the microcomputer in a low power consumption state (processing instructions), the first connection control signal 1
0 to a low level, cutting off the current path through the feedback resistor 9, setting the second connection control signal 15 to a high level, connecting a low frequency crystal oscillator to the terminals 16 and 17, and obtaining an oscillation signal. Can be used as a microcomputer system clock. Therefore, since the microcomputer operates at a low frequency, it is possible to process instructions with low power consumption.

The first and second connection control signals may be set to a high level or a low level by a command from the microcomputer, or may be set externally by a predetermined terminal of the microcomputer.

The feedback resistor is composed of complementary metal oxide semiconductor transistors as shown in FIG. At the time of
By turning off the transistors 19 and 20, the impedance may be set to high, and whether the feedback resistor is connected or disconnected may be controlled.

〔Effect of the invention〕

As explained above, the present invention enables lower power consumption than in standby mode by controlling whether to connect or disconnect the feedback resistor for each of all oscillation circuits in a microcomputer that has two or more built-in multiple oscillation circuits. It has the effect of increasing the amount of change.

Another effect is that since the feedback resistor built into the microcomputer can be separated from the oscillation terminal, an optimal feedback resistor suitable for the oscillator can be externally attached.

8.13...Inverter circuit, 9.14 Old...
・Feedback resistance, 10.15... Connection control signal, 1
1,12゜16.17...Terminal.

FIG. 2 is a crystal oscillation configuration diagram for explaining the present invention.

l...Crystal oscillator, 2, 3...Terminal,
4゜5... Capacitor, 6... Inverter circuit, 7... Feedback resistor.

Figure 3 shows an example of the configuration of a feedback resistor using complementary metal oxide semiconductor transistors.

18... Connection control signal, 19... Mark: N-type metal oxide film semiconductor transistor, 2o... River: P-type metal oxide film semiconductor transistor.

Agent Patent Attorney Susumu Uchihara

[Brief explanation of the drawing]

FIG. 1 is a configuration diagram of an embodiment of the present invention.

Claims (1)

[Claims] In a microcomputer incorporating a plurality of oscillation circuits, the plurality of oscillation circuits include an inverter means, a feedback resistor means connected in parallel with the inverter means, and a control signal that controls whether or not the feedback resistor means is connected. A microcomputer with a built-in oscillation circuit, characterized by comprising connection control means.