CN201243226Y - Dynamic drive circuit for preventing station long hair defect - Google Patents

Abstract

The utility model relates to a dynamic drive circuit for preventing frequent malfunctions at radio stations. The dynamic drive circuit is suitable for an electric power load management terminal in a radio station, the radio station is connected with a terminal microcontroller by each serial interface thereof, wherein, the dynamic drive circuit is provided with an input end, an output end and a control end; the input end is connected with a request-sending end of the microcontroller, the output end is connected with a request-sending input end of the radio station, the control end is connected with a dynamic control signal from the microcontroller and determines whether to communicate the input end and the output end of the dynamic drive circuit by identifying whether the frequency of the dynamic control signal is in the normal frequency range, thereby avoiding frequent malfunctions at radio stations caused by the unexpected power failure of the terminal main control panel or the unexpected run-out of the terminal program.

Description

Prevent the dynamic driver circuit of permanent fault of broadcasting station

Technical field

The utility model relates to a kind of dynamic driver circuit that prevents permanent fault of broadcasting station that is used for electricity load management terminal.

Background technology

Electricity load management terminal has been widely used in the power automation field, generally the master station by Utilities Electric Co. passes through its omnidirectional antenna, send various command to the electricity load management terminal that is positioned at each industrial enterprise, and from the electricity load management terminal answer back code, extract data.

Electricity load management terminal generally all is installed on each industrial enterprise, and the remote control output of electricity load management terminal connects the line switching of each enterprise, controls production electricity consumption and household electricity respectively.Electricity load management terminal receives the guidance command of master station, and the electricity consumption data of each industrial enterprise are also gathered in opening and closing of the control circuit of controlling simultaneously, report master station, as the foundation of Utilities Electric Co.'s administration of power networks.

Because electricity load management terminal need carry out wireless two-way communication with master station.At present, the radio communication at electricity load management terminal has dual mode: a kind of is wireless public network communication (being so-called GPRS, cdma communication), and another is private network communication (radio set communication).

In private network communication, radio station carries out data interaction by serial line interface as a vitals of circuit load office terminal between radio station and the electricity load management terminal master control borad.Dual mode is roughly arranged in the existing application, and a kind of radio station directly links to each other with the serial ports of terminal microcontroller by its serial ports, as shown in Figure 1, and wherein:

The data sending terminal (TXD) of terminal master control borad 10 serial line interfaces directly connects the data receiver (RXD) of radio station 12;

The data receiver (RXD) of terminal master control borad 10 serial line interfaces directly connects the data sending terminal (TXD) of radio station 12;

The data sending request end (RTS) of terminal master control borad 10 serial line interfaces is directly connected to radio station's 12 data sending request inputs;

The conversation of terminal master control borad 10 serial line interfaces allows end (DTR) to be directly connected to the voice control end (DTR) of radio station 12;

The ground wire (GND) of microcontroller in the terminal master control borad 10 (figure does not show) directly is connected with the ground wire of radio station 12.

The prior art of another wireless private network communication is that the Data Receiving that data send, Data Receiving is directly connected to the terminal micro controller series, the data of radio station's serial ports send.The transmission request of microcontroller, the transmission request input, the permission conversation control end that allow to converse by electronic switching device and radio station are connected.As shown in Figure 2, wherein:

The data sending terminal (TXD) of terminal master control borad 20 serial line interfaces directly connects the data receiver (RXD) of radio station 22;

The data receiver (RXD) of terminal master control borad 20 serial line interfaces directly connects the data sending terminal (TXD) of radio station 22;

The ground wire of terminal master control borad 20 (GND) directly is connected with the ground wire of radio station 22.

The data sending request end (RTS) of terminal master control borad 20 serial line interfaces is connected to radio station 22 by electronic switch 24 and sends the request input;

The permission communicating end (DTR) of microcontroller in the terminal master control borad 20 (figure does not show) is connected to the permission conversation control end of radio station 22 by electronic switch 24.

It is simple that the advantage of the circuit of above-mentioned these prior aries is that circuit constitutes, and circuit realizes easily, debugging, produces all very conveniently, therefore is widely used in the electricity load management terminal.

Yet, because RTS is that low level is effective, the power down if terminal master control borad (10,20) meets accident, make RTS remain low level, and radio station (12,22) normal power supply, at this moment, radio station (12,22) power supply can be inculcated electric current to microcontroller by RTS, and protective circuit is protected these two signals with moving in the microcontroller, thereby causes radio station to be in the data transmit status all the time; If very likely can drag down the microcontroller program fleet RTS in this case, and cause the radio station long hair because certain uncertain factor makes.

If the power load management system of Utilities Electric Co. is same frequency range, if in system, there is a certain station terminal to be in the long hair state, can make that then master station is paralysed because of communicating by letter with other-end in the whole power load management system, this is a kind of very serious fault in power load management system.Therefore need a kind of scheme to make and in power load management system, avoid taking place above-mentioned fault.

The utility model content

Technical problem to be solved in the utility model provides a kind of dynamic driver circuit that prevents permanent fault of broadcasting station.

The utility model is that to solve the problems of the technologies described above the technical scheme that adopts be to propose a kind of dynamic driver circuit that prevents permanent fault of broadcasting station, be applicable to the electricity load management terminal that is contained in a radio station, serial line interface by separately between this radio station and the terminal microcontroller is connected, wherein this dynamic driver circuit has an input, one output and a control end, this input connects the transmission request end of this microcontroller, this output connects the transmission request input of this radio station, this control end connects the dynamic control signal from this microcontroller, and this dynamic driver circuit comprises: first frequency discriminator, second frequency discriminator, dynamic current driver and output switch.First frequency discriminator connects this control end, differentiates the frequency of this dynamic control signal, and the frequency of wherein working as this dynamic control signal is higher than the following of a predeterminated frequency scope prescribes a time limit, and this first frequency discriminator produces also exports an enable signal.Second frequency discriminator connects this control end and this first frequency discriminator and works when receiving this enable signal, second frequency discriminator is differentiated the frequency of this dynamic control signal, wherein the frequency when this dynamic control signal is lower than going up in limited time of a predeterminated frequency scope, and this second frequency discriminator produces and export second drive signal.The dynamic current driver connects this second frequency discriminator and produce an effective switching drive signal when this second frequency discriminator is output as this second drive signal.The output switch connects this input, this output and this dynamic current driver respectively, and this output switch makes this input be communicated with this output when this switching drive signal is effective.

In above-mentioned dynamic driver circuit, first frequency discriminator further comprises: the frequency discrimination unit, and it is identical with dynamic control signal and have first drive signal of one first ON time constant in each cycle to produce and export a frequency; And enable the unit, and connecting this first drive signal of this first frequency discriminator, the frequency of wherein working as this dynamic control signal is higher than the following of a predeterminated frequency scope prescribes a time limit, and this enables the unit and exports an enable signal.

In above-mentioned dynamic driver circuit, the frequency of this second drive signal is identical with dynamic control signal and have one second an ON time constant, and the frequency of working as this dynamic control signal is higher than going up in limited time of this predeterminated frequency scope, and this second frequency discriminator produces also exports a constant level signal.

In above-mentioned dynamic driver circuit, this frequency discrimination unit comprises monostable circuit, and wherein the timing end of this monostable circuit has electric capacity and the resistance of determining the described first ON time constant.

In above-mentioned dynamic driver circuit, this enables the unit and comprises the RC charging circuit.

In above-mentioned dynamic driver circuit, this second frequency discriminator comprises monostable circuit, and wherein the timing end of this monostable circuit has electric capacity and the resistance of determining the described second ON time constant.

In above-mentioned dynamic driver circuit, also comprise an input switch, be connected between this control end and this first frequency discriminator, and between this control end and this second frequency discriminator.

In above-mentioned dynamic driver circuit, under the transmission request input normality of this radio station by on draw and be high level.

Therefore, the utility model is by being provided with dynamic driver circuit on the microcontroller of electricity load management terminal and the RTS line between the radio station, the frequency of the dynamic control signal by differentiating microcontroller can guarantee that the terminal wireless radio station avoids producing permanent fault.

Description of drawings

For above-mentioned purpose of the present utility model, feature and advantage can be become apparent, below in conjunction with accompanying drawing embodiment of the present utility model is elaborated, wherein:

Fig. 1 is existing a kind of radio set communication schematic diagram.

Fig. 2 is existing another kind of radio set communication schematic diagram.

Fig. 3 is a schematic diagram of using the dynamic driver circuit that prevents permanent fault of broadcasting station according to embodiment of the utility model on the RTS line.

Fig. 4 prevents permanent fault of broadcasting station dynamic driver circuit structured flowchart.

Fig. 5 prevents permanent fault of broadcasting station dynamic driving control circuit figure.

Fig. 6 is microcontroller dynamic driver circuit output waveform figure when normally sending data.

Fig. 7 is microcontroller output RTSCTR frequency dynamic driver circuit output waveform figure when too low.

Fig. 8 is microcontroller output RTSCTR frequency dynamic driver circuit output waveform figure when too high.

Embodiment

Embodiment only is used to prove that it is attainable that this scheme adopts prior art, has the requirement of practicality, is not used in the scope of restriction claim, the dynamic driver circuit internal circuit of mentioning, and the chip model only is used to provide a kind of possible circuit implementation.

The purpose of this utility model provides a kind of dynamic circuit that is used for the anti-permanent fault of broadcasting station of electricity load management terminal, with reference to shown in Figure 3, is connected by its communications serial interface separately between terminal master control borad 30 and the radio station 32.With the serial line interface of terminal master control borad 30 sides, it has data sending terminal TXD, data receiver RXD, allows communicating end DTR, sends request end RTS and earth terminal GND.Wherein data sending terminal TXD, data receiver RXD, the conversation to serial line interface allows each end of end DTR still to adopt former design, and increased a dynamic driver circuit 34 between the RTS line that request end (RTS) is connected with radio station sending, even make master control borad that the fault of radio station's long hair also can not take place under the situation of power down or program fleet.

Accept above-mentioned, dynamic driver circuit 34 has an input RTS1, an output RTS2 and a dynamic control end RTSCTR, wherein RTS1 is connected with the RTS end of terminal master control borad 30, and RTS2 is connected with the RTS request input of radio station 32, as its drive signal.The RTSCTR end is connected with the IO mouth of microcontroller 33 by a dynamic route control 36, and the square-wave pulse of microcontroller 33 about RTSCTR output 500Hz drives dynamic driver circuit 34.In addition, when microcontroller 31 needed externally to send data, RTS1 held output low level, when microcontroller 31 does not send data, and RTS1 end output high level.

For realize that mainboard can not cause radio station the fault of long hair to occur under the situation of power down or program fleet, dynamic driver circuit 34 is configured to have following function:

When terminal under normal operation, when needing externally to send data, the serial line interface output low level of master control borad 30, this signal is input to the RTS1 end of dynamic driver circuit 34.The microcontroller 31 of master control borad 30 is opened the control gate of dynamic driver circuit 34 by the square-wave signal of a 500Hz of RTSCTR dynamic route control output simultaneously.At this moment, the RTS2 of dynamic driver circuit 34 just understands output low level.Radio station 32 recognizes RTS2 when being output as low level, allows to send data.

Dynamic driver circuit 34 is under following situation, and (high level) closed in RTS2 output, and radio station 32 forbids sending data:

1, RTS1 is a low level, and microcontroller 31 is not exported square-wave signal at dynamic control end RTSCTR, and the control gate of dynamic driver circuit 34 keeps closed condition, and output RTS2 keeps high level output, and radio station does not send data.

2, RTS1 is a low level, and the dynamic control end RTSCTR of microcontroller 31 output square-wave signal frequency (this situation may be because microcontroller 31 programs are walked to fly or something unexpected happened during greater than 1500Hz, the normal square wave frequency of dynamic control signal is about 500Hz), the control gate of dynamic driver circuit 34 keeps closed condition, output RTS2 keeps high level output, and radio station 32 does not send data.

3, RTS1 is a low level, and the dynamic control end RTSCTR of microcontroller 31 output square-wave signal frequency (this situation may be because microcontroller 31 programs are walked to fly or something unexpected happened during less than 250Hz, the normal square wave frequency of dynamic control signal is about 500Hz), the control gate of dynamic driver circuit 34 keeps closed condition, output RTS2 keeps high level output, and radio station 32 does not send data.

4, RTS1 is a high level, and the dynamic control end RTSCTR of microcontroller 31 exports normal square-wave signal, the control gate of microcontroller 31 is opened, if but input RTS1 is high level (microcontroller 31 does not ask to send data), therefore still keep high level on the output RTS2 of dynamic driver circuit 34, radio station 32 does not still send data.

5, the terminal master control borad partly cuts off the power supply, and radio station's power supply is normal.In this case, RTS2 remains high level equally, makes radio station can't send data.

The utility model comes down to by differentiating that frequency for the dynamic control signal of controller reaches above-mentioned functions.The operation principle of dynamic driver circuit is described below with reference to Fig. 4.This dynamic driver circuit 34 comprises input switch 40, first frequency discriminator 42, second frequency discriminator 44, dynamic current driver 46 and output switch 48.Input switch 40 is the input buffering levels as circuit 34.

First frequency discriminator 42 receives dynamic control signal RTSCTR, to differentiate the frequency of this dynamic control signal, having only the frequency of working as this dynamic control signal to be higher than the following of a predeterminated frequency scope prescribes a time limit, first frequency discriminator 42 just produces and exports an enable signal EN, high level for example, under other situations, what first frequency discriminator 42 was exported is the low level disable signal.Wherein the predeterminated frequency scope of dynamic control signal is the frequency that may occur during according to 31 power down of terminal microcontroller or program fleet and fixed.For example and without limitation, normal range (NR) for example is 250Hz～1500Hz, and its lower limit is 250Hz.Need to prove that the dynamic control signal of constant level can be regarded as the signal of 0Hz.

The enable signal EN of first frequency discriminator, 42 outputs is used for enabling second frequency discriminator.

Second frequency discriminator 44 receives dynamic control signal RTSCTR to differentiate this frequency.Yet second frequency discriminator 44 is only worked when receiving enable signal EN, under other situations, and the work that can be under an embargo of second frequency discriminator 44, its output is constant to be low level.When the work of second frequency discriminator 44, be lower than the upper limit of above-mentioned predeterminated frequency scope in the frequency of this dynamic control signal, promptly under the situation of 1500Hz, second frequency discriminator 44 produces also exports one second drive signal Drv2.This second drive signal is the dynamic current signal with certain frequency, for example square-wave signal.The frequency of this dynamic control signal be higher than 1500Hz in limited time, second frequency discriminator 44 can produce and export the signal of a voltage constant, for example high level.

Dynamic current driver 46 connects second frequency discriminator 44, and only just can produce an effective switching drive signal Gate when second frequency discriminator is output as the second drive signal Drv2, and it for example is a high level.And output switch 48 connects input RTS1, output RTS2 and the dynamic current driver 46 of dynamic driver circuit 34 respectively, and output switch 48 just makes input RTS1 and output RTS2 conducting when input Continuity signal On.

So, when having only frequency when dynamic control signal in normal range (NR) 250Hz～1500Hz, just can make input RTS1 and output RTS2 conducting, therefore under situation such as 30 power down of terminal master control borad or program fleet, the low level RTS signal of its output can't conduct to RTS2, thereby avoids radio station 32 permanent fault to occur.

In addition, output RTS2 in radio station 32 by by pull-up resistor normally to high level, the permanent fault to avoid terminal master control borad 30 power down under some extreme case under radio station's 32 normal power supply situations.

More further specify specific embodiment of the utility model below, please refer to Fig. 4, shown in Figure 5 with the circuit of a reality.

Dynamic control signal RTSCTR is connected to resistance R 1.Resistance R 1, R2, R3, triode Q1 form input switch 40 shown in Figure 4, and the waveform between the input and output of this input switch 40 is opposite.

The RTSCTR signal is input to first frequency discriminator 42 through behind the input switch 10.Its chips D1A, resistance R 4, capacitor C 1 are formed the frequency discrimination unit of first frequency discriminator 42, and the charging circuit composition that resistance R 5, capacitor C 2 are formed enables the unit.

D1A is a slice two-way monostable integrated circuit, and its configuration mode is: 5 pin of D1A are the pulse input signal trailing edge trigger end of monostable circuit, connect high level (not using) now; 3 pin of D1A are the set end of monostable circuit, connect high level (not using) now; 1 pin of D1A is the discharge end of monostable circuit, ground connection; 4 pin of D1A are the pulse input signal rising edge trigger end of monostable circuit; 6 pin of D1A are the output of monostable circuit; 2 pin of D1A are the output pulse timing end of monostable circuit, connect capacitor C 1 and resistance R 4.

It is each that monostable circuit just triggers once when rising edge occurring on 4 pin of D1A (monostable circuit is operated in rising edge and triggers), 6 pin of chip D1A output high level, and the duration of output high level is the τ 1 (time constant of R4 * C1).Behind the elapsed time constant, the 6 pin output low levels of D1A (high level and low level duty ratio are calculated through strict).Produce and export a frequency has the first ON time constant in and each cycle identical with the RTSCTR signal the first drive signal Drv1 thus.The charging to the first drive signal Drv1 is responsible in the unit that enables that R5, C2 form, to produce enable signal EN.

Chip D1B, resistance R 6, capacitor C 3 are formed second frequency discriminator 44.

D1B also is a slice two-way monostable integrated circuit, and its configuration mode is: 11 pin of D1B are the pulse input signal trailing edge trigger end of monostable circuit; 13 pin of D1B are the set end of monostable circuit, connect high level (not using) now; 15 pin of D1B are the discharge end of monostable circuit, ground connection; 12 pin of D1B are the pulse input signal rising edge trigger end of monostable circuit; 10 pin of D1B are the in-phase output end of monostable circuit; 14 pin of D1B are the output pulse timing end of monostable circuit.

Second frequency discriminator 44 triggers according to enable signal EN and works.Similarly in first frequency discriminator, when on 4 pin of D1B, rising edge occurring at every turn, monostable circuit just triggers once, the 6 pin output high level of D1B, the duration of output high level is the τ 2 (time constant of R6 * C3), behind the elapsed time constant, the 6 pin output low levels of D1B (high level and low level duty ratio are calculated through strict).Produce and export a frequency has the second ON time constant in and each cycle identical with the RTSCTR signal the second drive signal Drv2 thus.What deserves to be mentioned is that when the frequency of this RTSCTR signal was too high, it was a constant level signal that second drive signal will distort.

Following detailed operation principle is divided into four kinds of situations and is illustrated:

One, microcontroller 31 is in normal operating conditions, the working condition of dynamic driver circuit 34 when radio station 32 is sent data;

The output waveform of D1A pin 6 as shown in Figure 6.Behind the D1A pin 6 output square waves, by R5 C2 is charged when high level, C2 discharges by R5 when low level.The C2 charge and discharge process produces waveform as shown in Figure 6 on the pin 11 of D1A.When the RTSCTR signal has just begun input pulse, starting voltage is that 0V begins charging on 11 pin of D1B, because the duty ratio of the 6 pin output waveforms of D1A is bigger, therefore the voltage on D1B 11 pin increases along with umber of pulse and rises, when this voltage rises to the D1B threshold values when above, the Enable Pin of D1B can be opened.D1B output high level lasting time is the τ 2 (time constant of R6 * C3).Output waveform as shown in Figure 6 on D1B 10 pin.The frequency of output waveform is identical with D1A 6 pin on D1B 10 pin, and phase place is identical, unique different be the duty ratio difference.

The R9 of dynamic current driver 46 is received in the output (DPCOUT) of D1B 10 pin.Wherein resistance R 7, R8, R9, R10, diode D1, triode Q2 form a switching circuit.When D1B 10 pin output low levels, Q2 ends, and to capacitor C 4 chargings, capacitor C 4 is full of power supply VCC very soon by D1, R7, R8; When D1B 10 pin output high level, the Q2 conducting, C4 charges to C5 by Q2.In the C4 discharge process, V5 oppositely ends, and the discharging current of C4 all is sent on the C5, because of the plus earth of C5, in the C4 discharge process, the C5 cathode voltage can not rise, so the C5 cathode voltage is toward descending, because be provided with D3 in the circuit, in the C4 discharge process, D3 ends.Along with the further decline of C5 cathode voltage, photoelectrical coupler D4 will conducting, opens output switch 48 after the D4 conducting.After square-wave signal occurring on D1B 10 pin, the appearance said process that goes round and begins again on capacitor C 4 will soon reach the condition of enough triggering photoelectrical couplers conducting on the capacitor C 5.

Output switch 48 is made up of photoelectrical coupler D4, resistance R 13, R14, R15, triode Q3, Q4.After the photoelectrical coupler D4 conducting, the 4 pin output low levels of D4, but also conducting of Q3; But also conducting of Q4 after the Q3 conducting.Microcontroller 31 serial line interface RTS1 are connected on the emitter of Q4, the RTS2 of radio station's 32 serial line interfaces is connected on the collector electrode of Q4.After the Q4 conducting, the state of microcontroller 31 serial line interface RTS1 just can be reacted on the serial line interface RTS2 of radio station.

Two, microcontroller 31 does not send data to radio station 32 in normal operation; Perhaps microcontroller 31 is under abnormal operating state, the working condition of dynamic driver circuit 34 when " RTSCTR " output frequency is too low;

The working condition of dynamic driver circuit 34 was not the same when microcontroller 31 did not send data the RTSCTR signal output frequency is too low under abnormal operating state with microcontroller 31, the former is a kind of extreme case of the latter, and dynamic driver circuit each point waveform as shown in Figure 7.

When the frequency of RTSCTR input pulse signal is too low, because the timeconstant 1 (R4 * C1) constant of D1A, at the RTSCTR input pulse also when continuing high level, R4, C1 discharge finishes already, the time of D1A 6P output high level is constant, but the duty ratio of output waveform changes, as shown in Figure 7.Because the duty ratio of D1A 6P output waveform diminishes, so the charging interval of capacitor C 2 is shorter, and discharge time is longer, the super only threshold voltage of D1B thresholding (as shown in Figure 7) of the crest voltage of C2, the door of D1B is closed, and the output of D1B 10 pin is constant to be low level (as shown in Figure 7).

Because D1B 10 pin constant output low levels, Q2 is in cut-off state all the time, causes C4 not have discharge loop, and C5 does not have charge circuit, and photoelectrical coupler D4 is in cut-off state all the time.As long as photoelectrical coupler D4 is in cut-off state, output switch 48 is not just opened, and the state of microcontroller 31 serial line interface RTS1 can not be reflected on the RTS2 of radio station's serial line interface.

Can learn that through above-mentioned analysis even this circuit is held output low level at the RTS1 of microcontroller 31, as long as the RTSCTR output frequency of microcontroller 31 is too low, the RTS2 of radio station 32 also is in high level state, radio station 32 can externally not send data.

Three, microcontroller 31 is under non operating state, " RTSCTR " working condition of dynamic driver circuit when output frequency is too high;

When the frequency of RTSCTR input pulse signal is too high, because the timeconstant 1 (R4 * C1) constant of D1A, when R4, C1 discharge does not also finish, the rising edge of second pulse of RTSCTR occurs, the D1A monostable circuit is triggered again, at this moment, the 6 pin constant output high level (as shown in Figure 8) of D1A.

Because D1A 6 pin constant output high level, so be full of electricity on the C2 soon, and C2 do not have discharge loop, keeps high level (shown in the D1B 11 pin waveforms of Fig. 8) always, thus D1B enable open always.(R6 * C3) is less than the time constant of D1A, so the phenomenon that D1A heavily triggers also appears in D1B certainly, and D1B 10 pin are constant output high level (as Figure 81 0P waveform) also at the timeconstant of when design D1B.

Because D1B 10 pin constant output high level, Q2 is in conducting state all the time, causes the C4 velocity of discharge far above charging rate, does not therefore have voltage on the positive pole of C4 substantially, and C5 does not have charge and discharge process simultaneously yet, and photoelectrical coupler D4 can conducting yet.Not conducting of photoelectrical coupler D4, output switch 48 is in closed condition, and the state of microcontroller 31 serial line interface RTS1 can not embody on the serial line interface RTS2 of radio station, and RTS2 remains high level, thereby avoids occurring radio station's permanent fault.

Four, but the master control borad power down radio station at microcontroller 31 places continues power supply, the working condition of dynamic driver circuit.

In the unexpected for a certain reason dead electricity of terminal master control borad 30, but radio station 32 continues under the situation of power supply, dynamic driver circuit 34: input switch 40, first frequency discriminator 42, second frequency discriminator 44, dynamic current driver 46 are not worked, and output switch 48 cuts out.Because the RTS2 end has pull-up resistor in radio station 32 inside.Therefore, radio station permanent fault can not occur yet.

According to above-mentioned several situation analysis, dynamic driver circuit of the present utility model can guarantee that the terminal wireless radio station avoids producing permanent fault.

Though the utility model discloses as above with preferred embodiment; right its is not in order to limit the utility model; any those skilled in the art; in not breaking away from spirit and scope of the present utility model; when doing a little modification and perfect, therefore protection range of the present utility model is worked as with being as the criterion that claims were defined.

Claims (8)

1. dynamic driver circuit that prevents permanent fault of broadcasting station, be applicable to the electricity load management terminal that is contained in a radio station, serial line interface by separately between this radio station and the terminal microcontroller is connected, wherein this dynamic driver circuit has an input, an output and a control end, this input connects the transmission request end of this microcontroller, this output connects the transmission request input of this radio station, this control end connects the dynamic control signal from this microcontroller, it is characterized in that this dynamic driver circuit comprises:

First frequency discriminator connects this control end, differentiates the frequency of this dynamic control signal, and the frequency of wherein working as this dynamic control signal is higher than the following of a predeterminated frequency scope prescribes a time limit, and this first frequency discriminator produces also exports an enable signal;

Second frequency discriminator, connect this control end and this first frequency discriminator and when receiving this enable signal, work, second frequency discriminator is differentiated the frequency of this dynamic control signal, wherein the frequency when this dynamic control signal is lower than going up in limited time of a predeterminated frequency scope, and this second frequency discriminator produces and export second drive signal;

The dynamic current driver connects this second frequency discriminator, and produces an effective switching drive signal when this second frequency discriminator is output as this second drive signal; And

The output switch connects this input, this output and this dynamic current driver respectively, and this output switch makes this input be communicated with this output when this switching drive signal is effective.

2. dynamic driver circuit as claimed in claim 1 is characterized in that, this first frequency discriminator comprises:

The frequency discrimination unit, it is identical with dynamic control signal and have first drive signal of one first ON time constant in each cycle to produce and export a frequency; And

Enable the unit, connect this first drive signal of this first frequency discriminator, the frequency of wherein working as this dynamic control signal is higher than the following of a predeterminated frequency scope prescribes a time limit, and this enables the unit and exports an enable signal.

3. dynamic driver circuit as claimed in claim 1, it is characterized in that, the frequency of this second drive signal is identical with dynamic control signal and have one second an ON time constant, and the frequency of working as this dynamic control signal is higher than going up in limited time of this predeterminated frequency scope, and this second frequency discriminator produces also exports a constant level signal.

4. dynamic driver circuit as claimed in claim 2 is characterized in that, this frequency discrimination unit comprises monostable circuit, and wherein the timing end of this monostable circuit has electric capacity and the resistance of determining the described first ON time constant.

5. dynamic driver circuit as claimed in claim 2 is characterized in that, this enables the unit and comprises the RC charging circuit.

6. dynamic driver circuit as claimed in claim 3 is characterized in that, this second frequency discriminator comprises monostable circuit, and wherein the timing end of this monostable circuit has electric capacity and the resistance of determining the described second ON time constant.

7. dynamic driver circuit as claimed in claim 1 is characterized in that also comprising an input switch, is connected between this control end and this first frequency discriminator, and between this control end and this second frequency discriminator.

8. dynamic driver circuit as claimed in claim 1 is characterized in that, the request of this radio station send input normally by on draw and be high level.

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