JPH0441374Y2 - - Google Patents

Description

[Detailed Description of the Invention] (a) Field of Industrial Application The present invention relates to an oscillation format switching circuit that switches between oscillation circuits of different oscillation formats built into a microcomputer or the like.

(B) Prior Art Generally, a 4-bit or 8-bit one-chip microcomputer has a built-in oscillation circuit for creating a system clock for controlling system operations. Recently, some microcomputers have a plurality of built-in oscillation circuits with different oscillation formats so that the oscillation format can be selected according to the purpose of use of the microcomputer, and the oscillation circuits can be switched by a control signal.

FIG. 2 is a circuit diagram showing a conventional oscillation format switching circuit. 1 is an RC oscillation circuit, which is composed of a Schmitts inverter 2, a NOR gate 3 to which a control signal OSC CONT is applied, and an inverter 4 made up of C-MOS, and the input of Schmitts inverter 2 is connected to an external terminal 5. A transmission gate 7 controlled by a control signal RC/CF is connected between the output of the inverter 4 and the external terminal 6. 8
is a ceramic oscillator circuit, and the control signal OSC
The control signal is connected between the C-MOS configuration NAND gate 9 to which CONT is applied and the external terminals 5 and 6.
It consists of a transmission gate 10 controlled by RC/CF, one input of NAND gate 9 is connected to external terminal 5, and a control signal RC/CF is connected between the output of NAND gate 9 and external terminal 6. A transmission gate 11 controlled by is connected. The transmission gate 10 of the ceramic oscillation circuit 8 acts as a feedback resistor when the ceramic oscillation circuit 8 is selected.

The control signal OSC CONT controls the start and stop of oscillation of the RC oscillation circuit 1 and the ceramic oscillation circuit 8, and when a halt command is executed, it becomes "1" and stops the oscillation, and the halt state is released. The signal becomes "0" and starts oscillation.

The control signal RC/CF is for selecting the RC oscillation circuit 1 and the ceramic oscillation circuit 8.
When RC/CF is "1", only transmission gate 7 is turned on and RC oscillation circuit 1 is selected; when control signal RC/CF is "0", only transmission gate 11 is turned on. Ceramic oscillation circuit 8 is selected. Although the RC oscillation circuit 1 has poor oscillation frequency stability, it can obtain sufficient oscillation output immediately after the start of oscillation, so it is used when it is desired to operate the microcomputer immediately after releasing the halt state.
Connect a resistor and a capacitor between external terminals 5 and 6. On the other hand, the ceramic oscillation circuit 8 requires a certain amount of time from the start of oscillation until the oscillation stabilizes, but because the oscillation frequency is stable and a high oscillation frequency can be obtained, it is used when operating a microcomputer at high speed. At this time, a ceramic vibrator and a capacitor are connected to external terminals 5 and 6.

The oscillation circuit shown in Figure 2 was
It is described on page 237 of ``'87 Sanyo Semiconductor Data Book, Microcomputer, Memory, Gate Array Edition,'' published by CQ Publishing Co., Ltd. in Japan.

(c) Problems to be solved by the invention Schmitt inverter 2 constituting the RC oscillation circuit 1 and ceramic oscillation circuit 8 shown in FIG.
When the input voltage of the NAND gate 3, inverter 4, and NAND gate 9 crosses an intermediate potential between the power supply voltage _VDD and the ground voltage _VSS due to continued oscillation, a through current flows through each element. Therefore, as the oscillation frequency becomes higher, the current consumption increases.
It is necessary to consider reducing the current consumption in the oscillation circuit as much as possible.

(d) Means for solving the problem The present invention was created in view of the above-mentioned points, and separates the connection points of P-channel MOS and N-channel MOS that constitute the output stages of multiple oscillation circuits. At the same time, one connection point of the P-channel MOS and N-channel MOS constituting the transmission gate that selects the oscillation circuit is separated, and each P-channel MOS and each N-channel MOS are connected to each other.
By connecting MOSs in series, the through current flowing to the output stage of each oscillation circuit is reduced.

(E) Effect According to the above-mentioned means, the through current flowing through the P-channel MOS and N-channel MOS that constitute the output stage of each oscillation circuit is transmitted through the P-channel MOS and N-channel MOS of the transmission gate that selects the oscillation circuit. Since the current flows through the transmission gate, the through current decreases due to the on-resistance of the P-channel MOS and N-channel MOS of the transmission gate.

(F) Embodiment FIG. 1 is a circuit diagram showing an embodiment of the present invention.
This is an example of an oscillation format switching circuit built into a microcomputer. The RC oscillation circuit 12 includes a Schmitt inverter 13, a control signal, and
NOR gate 14, C with OSC CONT applied
- Consists of an inverter 15 composed of MOS,
The ceramic oscillation circuit 16 also has a C-
It consists of a NAND gate 17 made up of MOS, and a transmission gate 20 connected between external terminals 18 and 19 and serving as a feedback resistor. Transmission gates 21 and 22 controlled by control signals RC/CF are provided between each output of the RC oscillation circuit 12 and the ceramic oscillation circuit 16 and the external terminal 19. The feature of the present invention is that the RC oscillation circuit 1
2 and the output of the ceramic oscillation circuit 16 and the transmission gates 21 and 22 are connected.

The output stage of the RC oscillation circuit 12 is a P channel.
It is composed of MOS Q ₁ and N-channel MOS Q ₂ , but the drain electrodes of each MOS Q ₁ and Q ₂ are not connected to each other, and the transmission gate 2
1 P channel MOS Q ₃ and N channel MOS
In _Q4 , the electrode on the external terminal 19 side is connected, but the electrode on the opposite side is not connected. And P channel
The drain of MOS Q ₁ is connected to the electrode of P channel MOS Q ₃ of transmission gate 21, and the drain of N channel MOS Q ₂ is connected to the electrode of N channel MOS Q 3 of transmission gate 21.
Connected with _Q4 electrode.

Furthermore, the NAND gate 17 of the ceramic oscillation circuit 16 is a P channel MOS Q ₅ connected in parallel.
and N-channel MOS Q ₇ connected in series with Q ₆
and Q ₈ , but P channel MOS
The drains of Q ₅ and Q ₆ and the drain of N-channel MOS Q ₇ are not connected, and similarly to the above, the drains of P-channel MOS Q ₅ and Q ₆ are connected to the electrode of P-channel MOS Q ₉ of the transmission gate 22. The drain of the N-channel MOS Q ₇ is connected to the electrode of the M-channel MOS Q ₁₀ of the transmission gate 22.

Therefore, the control signal RC/CF becomes "1",
When the transmission gate 21 is turned on, the RC oscillation circuit 12 is selected, but the through current flowing through the output stage inverter 15 is divided into the P channel MOS Q ₃ and the N channel MOS Q ₄ of the transmission gate 21. Since it flows as shown by the arrow, P channel MOS Q ₃ and N channel
The on-resistance of MOS Q ₄ reduces the through current. On the other hand, when the control signal RC/CF is "0", the transmission gate 22 is turned on and the ceramic oscillation circuit 16 is selected, but the NAND
The through current flowing through the gate 17 is a P channel.
MOS Q ₅ to P-channel MOS Q ₉ and N-channel MOS Q ₁₀ of transmission gate 22
The flow flows through the N channel MOS Q ₇ and Q ₈ as shown by the arrow, so the P channel MOS Q ₉ and N
The on-resistance of the channel MOS Q ₁₀ reduces the through current.

In this way, the through current flowing in the output stage of the RC oscillation circuit 12 and the ceramic oscillation circuit 16 is reduced by the RC
The through current is reduced by flowing through the P channel MOS and N channel MOS of the transmission gates 21 and 22 which select the oscillation circuit 12 and the ceramic oscillation circuit 16.

(g) Effects of the invention As described above, according to the invention, the current consumption in an oscillation circuit that can select different oscillation formats is reduced, contributing to lower power consumption in microcomputers and the like.

[Brief explanation of drawings]

FIG. 1 is a circuit diagram showing an embodiment of the present invention, and FIG. 2 is a circuit diagram showing a conventional example. 12...RC oscillation circuit, 16...Ceramic oscillation circuit, 21, 22...Transmission gate.

Claims (1)

[Scope of utility model registration request] two external terminals to which an oscillation element is connected, a plurality of oscillation circuits with different oscillation formats whose inputs are connected to one of the external terminals, and between the output of each of the oscillation circuits and the other of the external terminals. an oscillation type switching circuit comprising a transmission gate and a transmission gate to which a switching control signal is applied to the gate electrode;
P that separates the connection point between the MOS and the N-channel MOS and constitutes the transmission gate.
An oscillation format switching circuit characterized in that one connection point between a channel MOS and an N channel MOS is separated, and each P channel and each N channel are connected.