DE4345087A1 - Reset circuit - Google Patents

Abstract

A digital system is released from reset during power-up initialisation only when the system clock 9 has operated for a predetermined period sufficient for the clock to stabilise. The clock may be detected by a capacitor-diode circuit 11, 17, 15 feeding an RC integrator 19, 20 acting as a timer. Alternatively, the RC circuit may be fed by a current source 43 gated by a monostable 45 (figure 5), or the clock may be applied to a counting chain to produce a delay (figures 4 and 6). <IMAGE>

Description

Field of the Invention

The present invention relates to microprocessors, microcomputers, microcontrollers and other control logic circuits with free running clock driver or clock state, which in hereinafter referred to briefly as "control", and in particular to a reset switch circuit (reset circuit) for this.

Background of the Invention

When the controller is switched on, it receives both a DC voltage and a DC voltage power as well as a clock signal from a clock source or a clock generator. The control must reset with a so-called reset or reset as soon as voltage and have stabilized the clock signal. The reset signal (the release of a logical block learning levels) may be present for a longer period of time than for the Stabilization of the clock generator or the clock source of the control is necessary to ensure len that the resetting of the control does not take place until the clock source stabilizes is. Typically, a resistor / capacitor time circuit is used, the voltage of which drives or switches a Schmitt trigger. The output of the Schmitt trigger provides that Reset signal or reset signal ready.

With a simple time-controlled or time-delayed reset source, as above described, there is no physical guarantee that the timer or clock is fully operational before the provision is deployed. In many cases this can have serious consequences when controlling for the operation of a public supply systems, e.g. B. a telephone switching system is used.

With the term "supplying a reset signal to a control or other device" is intended be expressed that the correct polarity of a reset DC voltage levels, values or pulses is supplied, which is a logical blocking level or one Logical blocking value removed from a reset or blocking connection of the controller. It is therefore understood that the application or supply of a reset signal in the same Effectively the importance of removing a reset signal or providing one Reset signal to allow the processor to operate could be attributed.  

Summary of the invention

According to the present invention, the clock signal itself is used as an energy source for one Reset timer or time switch instead of the current / voltage supply (power ver supply) used. The clock signal is kept at a DC voltage level (black value circuit), rectified and then loads a resistance-capacitor time circuit, the preferably a leakage resistor or another leakage current path which has the charge from the capacitor in the time loop at a slightly slower rate than the one with which the time circle is loaded. A clamping diode or diode clamping circuit is used preferably used to discharge the capacitor in case the voltage drops like this also happens in a normal reset circuit.

According to one embodiment of the invention, a reset circuit consists of a Direct current or direct voltage source, a clock signal source, a device for applying the voltage from the voltage source to the clock source, a time circuit device, one Device for starting the timing by the timing circuit device from the clock signals of the Clock signal source, and a device for generating a reset signal following one fixed interval, which is timed by the time circuit device.

According to another embodiment of the invention, the reset circuit consists of a Device for receiving an oscillator or clock signal and a device therefor to generate a reset signal.

Brief description of the figures

A better understanding of the invention can be obtained from the detailed description below in conjunction with the subsequent drawings, of which:

Fig. 1 is a schematic diagram of a reset circuit according to the prior art,

Fig. 2 is a schematic diagram of an embodiment of the present invention,

Figure 3 is a graph illustrating the waveforms found in various sections of the circuit according to the invention, and

Figures 4, 5 and 6 are block diagrams illustrating additional embodiments of the invention.

Detailed description of the invention

Fig. 1 illustrates a prior art reset circuit used for a controller. A DC voltage source +, which supplies the clock 9 and a controller (not shown), which is to be reset, with energy, sends current through a resistor 1 to charge the capacitor 3 . While the capacitor 3 is being charged, a Schmitt trigger, which is connected to the connection between the resistor and the capacitor, is actuated or switched at a specific voltage. Its output signal is inverted in inverter 7 , and the output of inverter 7 is a / RESET signal for control. This resets the controller, which operates in a well known manner to execute a start program or initialization program.

Regardless of whether the DC power supply is stable or not, that is what happens Charging of the capacitor definitely takes place and at a certain time there is Reset signal the control free. The clock signal source, however, which also is operated from the voltage supply, at the time when the / RESET is present, working or ready for operation or not or may be stable or not.

Fig. 2 illustrates a schematic diagram of the present invention. The voltage source +, which supplies the controller with energy, is applied to the clock source or timer source 9 . The clock signal line is connected by means of a capacitor 11 and a memory 13 (which may be inverting or non-inverting) to a DC voltage restorer and rectifier, which consists of a diode 15 and a diode 17 , which are connected in series and polarized in the same way. The anode of diode 15 is connected to ground and capacitor 11 is connected to the connection of the two diodes.

The cathode of the diode 17 is connected to a resistance-capacitor time circuit, the cathode of the diode 17 being at one end of the resistor 19 and the capacitor 20 being connected between the other end of the resistor 19 and ground. A high-resistance bleeder resistor 21 is connected in parallel to the capacitor 20 .

The connection of the resistor 19 to the capacitor 20 is connected to the input of the Schmitt trigger 23 , the output of which is connected to a reset line 27 via the inverter 25 .

Another diode 29 , whose anode is connected to the connection between resistor 19 and capacitor 21 , is connected with its cathode to the voltage supply connection +.

In operation, when the system is turned on, the level of the power supply voltage increases. The timer or clock source 9 begins to operate. The clock signal is AC coupled to the DC restorer and rectifier, which consists of diodes 15 and 17 , where it is converted to DC voltage. The resulting DC voltage signal is applied to the resistance-capacitor time circuit, which operates in a similar manner to that in the prior art and charges the capacitor 20 . As soon as this is loaded to a predetermined level, the Schmitt trigger 23 is actuated or begins to work and its signal or its inverted signal, which is provided by the operation of the inverter 25 , is given to the reset line 27 , which is connected to the processor lies.

It can be seen that the capacitor 20 is only charged when clock pulses are generated. Therefore, the capacitor 20 is not only not charged when the clock is not working, contrary to the prior art as described above, but it also, since it is the clock pulses themselves that cause the capacitor 20 to charge, that Time delay of the voltage on the capacitor 20 to rise to the limit voltage for the operation or switching of the Schmitt trigger sufficient time for the clock signal ready to become stable.

In the prior art, the reset signal, because it is due to the presence of the Supply voltage has been provided to be present before the timer source was operational or during the first cycle or the first few cycles of the Timer source if it can still be unstable. This can be done with the present invention not happen because the existence of the clock signal itself for a certain period of time Generation of the reset signal causes.

As a safety factor, the clamp diode 29 is biased in the event that the main power supply drops, causing the capacitor 21 to discharge and causing the / RESET signal to be logically removed.

Resistor 21 , which derives charge from capacitor 20 , causes the voltage on capacitor 20 to drop in the event of timer 9 stop, causing the Schmitt trigger to logically remove the / RESET signal from line 27 and so that the control stops.

In a successful embodiment, the resistor 19 was 100K Ω, the capacitor 20 was 0.1 µF, the capacitor 11 was 0.1 µF and the diodes 15 and 17 were of the 1N4148 type. The resistor 21 had an M Ω.

It can be seen that the circuit works even without the presence of the resistor 21 or the diode 29 . The circuit also works with another resistor in series with the diode 15 and of course other values of the components can be selected for a special application.

Those skilled in the art will readily recognize that resistor 19 and capacitor 21, with their selectively associated components, constitute a time loop device. In an alternative embodiment of the invention, the time circuit device could consist of a capacitive charge storage element which is charged and discharged by current sources and current sinks. In a further alternative embodiment of the invention, as shown in Fig. 4, the timer device could consist of a digital counter 39 which is incrementally incremented by pulses from the clock or the clock source 9 and which could optionally be counted down by pulses from one second clock source 41 with a frequency which is slightly lower than the frequency of the first clock source.

Furthermore, it is possible to replace the time circuit function of the resistor 19 and the capacitor 21 by a counting chain which is operated directly by the buffer store 13 .

In addition, it can be seen that the capacitor 11 , the diode 15 and the diode 17 form a device which triggers the timing by the timing circuit device from clock signals from the clock signal source. In an alternative embodiment of the invention, as shown in FIG. 5, the device which triggers or starts the timing of the timing circuit device from clock signals of the clock signal source could consist of a current source 43 which is gated by a monostable multivibrator 45 , which is triggered by the pulses of the clock signal source, as shown.

The entire time delay circuit could optionally be replaced by a count chain 47 , with diode 27 and resistor 21 being replaced by a diode 49 with reset to the chain or a missing pulse detector 51 , as shown in FIG. 6.

FIG. 3 illustrates the signals at various points in the circuit of FIG. 2. Curve A shows a curve which shows the output voltage of the clock source or timer source 9 . No clock pulses appear in curve A before the timer is started, as shown at 31 . Once the timer has started operating, the extremes of the clock signal pulses shown at 33 can be clearly seen.

The voltage across capacitor 21 is shown as curve B, which, as shown at 35 , begins to rise as soon as clock signals are generated by timer 9 . Curve C illustrates the RESET signal at the output of Schmitt trigger 23 . The voltage stage 37 occurs at a point in time after the start of the operation of the timer and is determined by the limit value of the operation or switching of the Schmitt trigger and the speed of the rise in the voltage on the capacitor 21 .

During this circuit for the provision of a reset circuit for a controller has been described, it could alternatively be used to compensate for the loss of a monitor permanent or almost permanent clock or a changing data stream. The timing circuit device and the timing circuit triggering device Direction from the clock signal source could of course also be any practical Have a combination of analog or digital circuit elements. The resistances can solid-state channels or monolithic channels or semiconductor channels or others Current limiting sources, and the capacitors could be any circuit or other element that has a capacity.

A person who understands the present invention can now use alternative structures and Consider embodiments or variations of the above. These all which fall within the scope of the appended claims are considered part of the present Viewed invention.

Claims (17)

1. Reset circuit with:

• a) a DC voltage source,
• b) a clock signal source,
• c) devices for supplying energy from the voltage source to the clock signal source,
• d) a time cycle device,
• e) a device for triggering the timing by the time circuit device from the clock signals of the clock signal source,
• f) Devices for generating a reset signal following a predetermined interval, which is timed by the time circuit device.

2. Reset circuit according to claim 1, wherein the triggering device from one DC voltage generating circuit, which receives the clock signals and derives and outputs a DC voltage signal from this. 3. reset circuit according to claim 2, characterized in that the equal voltage generation circuit is a DC voltage recovery circuit, which is AC connected to the output of the clock signal source. 4. reset circuit according to claim 3, characterized in that the time circuits direction is a resistance-capacitor time circuit, including a device for Charging the capacitor from the DC recovery circuit output forth. 5. Reset circuit according to claim 4, characterized in that the reset signal generating device consists of a Schmitt trigger that has an off has release limit, which is slightly below the maximum predetermined equal voltage, which is the capacitor when the clock signal source is in stable operation reached. 6. reset circuit according to claim 5, characterized in that it also has a having high resistance across the capacitor to the capacitor discharge at a speed that is lower than the loading speed.   7. reset circuit, characterized by a device for receiving a oscillating signals or clock signals and a device for generating a Reset signals from this. 8. reset circuit according to claim 7, characterized by a device for Converting the oscillating or clock signal into a DC voltage signal and for the operation of a time circuit generating a reset signal with that. 9. reset circuit according to claim 8, characterized by a device for Providing a voltage source, the reset signal and the oscillating or Clock signals for a controller, for the power supply, clocking and resetting the Control. 10. Reset circuit according to claim 2, characterized in that the one is equal voltage generating circuit has a power source by a monostabi len multivibrator is gated, which of the pulses from the clock signal source is triggered or controlled. 11. Reset circuit according to claim 10, characterized in that the time circuits direction has a capacitive charge storage element, which is controlled by the gate Power source is being charged. 12. Reset circuit according to claim 11, characterized in that it also has a Device for discharging the capacitive charge storage element with a lower speed than the loading speed from the gated Has power source. 13. Reset circuit according to claim 12, characterized in that the discharge device device has a high resistance in parallel with the capacitor 14. Reset circuit according to claim 12, characterized in that the discharge device device has a current sink. 15. Reset circuit according to claim 1, characterized in that the time circuits direction has a digital counter circuit.   16. Reset circuit according to claim 15, characterized in that the trigger device a device for incrementally increasing the digital counter switch Circle with each occurrence of a pulse from the clock signal source. 17. Reset circuit according to claim 15, characterized in that the device for Generating the reset signal means for comparing the state of the digital counter circuit having a predetermined limit. 18. Reset circuit according to claim 15, characterized in that it also has a Device for gradually reducing or counting down the digital counter switch circuit every time a pulse from a second clock signal source occurs, which operates at a frequency that is significantly lower than the frequency of the first Clock signal source.