CN202818095U - A monitoring device and a vehicle-mounted electronic control device - Google Patents

Abstract

The utility model provides a monitoring device and a vehicle-mounted electronic control device which guarantee higher failure protection performance when used in an action monitoring structure of a control device such as a microcomputer or the like by using charging and discharging of a capacitor. The charging circuit of the monitoring device charges a capacitor by providing first current via a first path, while the discharging circuit of the monitoring device correspondingly and periodically inputs a monitoring signal to the control device in order to discharge the capacitor. When charging voltage of the capacitor reaches a specified value, a signal output circuit outputs a signal indicating absence of the monitoring signal in order to constrain the charging circuit to charge the capacitor by providing second current via a second path under the condition that the first current of the charging circuit is unsupplied. The second current is larger than the first current while the second path is different from the first path. The vehicle-mounted electronic control device comprises the monitoring device, a microcomputer, and a capacitor.

Description

Monitoring arrangement and vehicle-mounted type electronic-controlled installation

Technical field

The utility model relates to a kind of device of the operate condition for monitoring control device and the electronic-controlled installation that carries out the control of various vehicle-carrying mechanisms in the vehicle lift-launch.

Background technology

The electronic-controlled installation that ECU etc. carry at vehicle utilizes from the various loads of signal controlling of microcomputer output.The supply voltage of microcomputer requires proper range, if break away from the factor microcomputer such as this scope because of supply voltage out of control, then sometimes load meeting produces malfunction.

The electronic-controlled installation of vehicle-mounted type (particularly engine control system, steering control device, arrester control device etc. carry out the device of the control relevant with advancing, turn, stop to travel of these vehicles), the fail safe performance of having relatively high expectations.Therefore, known a kind of to the action of microcomputer or the device that monitors to the supply voltage that microcomputer applies.For example, known following structure: monitor supervision (watch dog) signal (hereinafter referred to as the WD signal) of periodically exporting from the microcomputer of regular event, continuous detecting does not go out in the situation of this WD signal within a certain period of time, it is out of control to judge that microcomputer occurs, to microcomputer output reset signal.

In order to detect the process of certain hour, supply with electric current and charge to capacitor, corresponding with the input of WD signal and to this discharging capacitors.If the WD signal is within a certain period of time continuously input not, then charging voltage reaches setting, judges that accordingly the WD signal does not exist, i.e. microcomputer unusual (for example, with reference to patent documentation 1,2).

Patent documentation 1: TOHKEMY 2001-111399 communique

Patent documentation 2: Japanese kokai publication hei 3-217364 communique

The utility model content

The action of above-mentioned monitoring arrangement, take the charging of capacitor, namely to the electric current supply of capacitor normally as prerequisite.Yet, in the used for charging source, produce unusual and in the situation that capacitor is not charged normal, following situation may occur: in the non-existent while of WD signal, the charging voltage of capacitor does not reach setting, can't detect the unusual of microcomputer.For example, external resistive element on monitoring arrangement generates based on the resistance value of this resistive element in the situation of used for charging stream, can produce the factor such as aging of beyond thought impact or connecting portion and resistive element breaks away from, thereby produces the unusual of used for charging source.

Therefore, the purpose of this utility model is, in the structure that the action of using discharging and recharging of capacitor to carry out the microcomputer equal controller monitors, provides the technology that can guarantee higher fail safe performance.

To achieve these goals, and the 1st mode of the present utility model is a kind of monitoring arrangement that the operate condition of control device is monitored, it has:

Charging circuit, it supplies with the 1st electric current by the 1st path, and capacitor is charged;

Discharge circuit, it is corresponding to the supervisory signal of periodically inputting from control device, to described discharging capacitors;

Signal output apparatus, its charging voltage at described capacitor reaches in the situation of setting, the non-existent signal of the output described supervisory signal of expression; And

The forced charge circuit, it by 2nd path different from described the 1st path, supplies with 2nd electric current larger than described the 1st electric current in the situation that the supply that detects from described the 1st electric current of described charging circuit stops, described capacitor is charged.

According to this structure, in charging circuit, produce unusually and in the situation that capacitor does not charge normal, utilize charging circuit by the path different from the electric current supply path capacitor to be charged rapidly, forcibly the non-existent signal of output expression supervisory signal.Therefore, can avoid following situation: in the non-existent while of supervisory signal, because the charging voltage of the unusual capacitor of charging circuit does not reach setting, can't detection control apparatus unusual.Therefore, can provide the fail safe performance higher monitoring arrangement.

Also can constitute, described forced charge circuit makes the charging voltage of described capacitor reach described setting within the time shorter than the input cycle of described supervisory signal.In this case, though in the unusual generation of the fault of charging circuit and control device just in case in the simultaneous situation, also can avoid occuring to judge the unusual situation of control device.

For example can constitute, described forced charge circuit has: the 1st transistor, and when the supply of described the 1st electric current stopped, the 1st transistor became off-state; The 2nd transistor, when described the 1st transistor became off-state, the 2nd transistor became on-state, when described the 2nd transistor becomes on-state, supplied with described the 2nd electric current to described capacitor.

Here, also can constitute, described forced charge circuit has comparator, when it becomes off-state at described the 1st transistor, make described the 2nd transistor become on-state, also can have constant-current source, when its supply at described the 1st electric current stops, making described the 1st transistor become off-state.

The utility model also can suitably be applicable to following structure: generate described the 1st electric current by the external resistance that is connected with described charging circuit.Insufficient with the connection of impact and aging and external resistance because of beyond thought vibration, be the main cause of the fault of charging circuit, in this case, by exporting forcibly the non-existent signal of expression supervisory signal, can notify the fault of charging circuit.

In order to realize above-mentioned order, the vehicle-mounted type electronic-controlled installation of the 2nd mode of the present utility model has:

Microcomputer;

Capacitor;

Charging circuit, it supplies with the 1st electric current via the 1st path, and described capacitor is charged;

Discharge circuit, it is corresponding to the supervisory signal of periodically inputting from described microcomputer, to described discharging capacitors;

Signal output apparatus, its charging voltage at described capacitor reaches in the situation of setting, the non-existent signal of the output described supervisory signal of expression; And

The forced charge circuit, it by 2nd path different from described the 1st path, supplies with 2nd electric current larger than described the 1st electric current in the situation that the supply that detects from described the 1st electric current of described charging circuit stops, described capacitor is charged.

According to this structure, in charging circuit, produce unusually and in the situation that capacitor does not charge normal, utilize charging circuit by the path different from the electric current supply route capacitor to be charged rapidly, forcibly the non-existent signal of output expression supervisory signal.Therefore, can avoid following situation: do not exist simultaneously in supervisory signal, because the charging voltage of the unusual capacitor of charging circuit does not reach setting, can't detect microcomputer unusually.Therefore, can provide the fail safe performance higher vehicle-mounted type electronic-controlled installation.

Also can constitute, described signal is the signal that described microcomputer is resetted, and the charging voltage that described rapidly charging circuit is kept described capacitor reaches the state of described setting.In this case, owing to keep the reset mode of microcomputer, so can prevent under the state of charging circuit fault, restarting electronic-controlled installation.Therefore, fail safe performance further improves.

Description of drawings

Fig. 1 is the functional block diagram of the structure of the monitoring arrangement that relates to of 1 execution mode of the present utility model.

Fig. 2 is the figure for the action of the monitoring arrangement of key diagram 1.

Fig. 3 is the figure for the action of the monitoring arrangement of key diagram 1.

Fig. 4 is the figure for the action of the monitoring arrangement of key diagram 1.

Fig. 5 is charging circuit and the circuit diagram of the 1st structure example of charging circuit rapidly in the monitoring arrangement of presentation graphs 1.

Fig. 6 is charging circuit and the circuit diagram of the 2nd structure example of charging circuit rapidly in the monitoring arrangement of presentation graphs 1.

Fig. 7 is charging circuit and the circuit diagram of the 3rd structure example of charging circuit rapidly in the monitoring arrangement of presentation graphs 1.

Embodiment

With reference to accompanying drawing the utility model is carried out following detailed description.In addition, each accompanying drawing that uses in the following description, the Comparative Examples chi suitably changes in order to become the size that can identify all parts.

Fig. 1 is the functional block diagram of the structure of the monitoring arrangement 100 that relates to of expression 1 execution mode of the present utility model.Monitoring arrangement 100 is installed among the ECU 200 as vehicle-mounted type electronic-controlled installation of the present utility model.ECU 200 has microcomputer 201 and capacitor 202.ECU 200 mainly carries out (advance, turn round, stop) the relevant control of travelling with vehicle, comprises engine control, turns to control, brake control etc.

Monitoring arrangement 100 has charge-discharge control circuit 110, signal output apparatus 130 and charging circuit 140 rapidly.They can realize each function of following explanation, for convenient and title is distinguished, do not get rid of the situation that the same circuit that is installed in the monitoring arrangement 100 moves as the circuit of different names.

Microcomputer 201 constitutes, and periodically exports supervisory signal (hereinafter referred to as the WD signal) when normal operation.Monitoring arrangement 100 constitutes, and the state of not exporting at certain hour by detecting the WD signal is judged the abnormal operation that waits microcomputer 201 out of control.

Charge-discharge control circuit 110 works as charging circuit of the present utility model, constitutes by the 1st path 111 to charge to capacitor 202 supplies the 1st electric current I 1.In addition, charge-discharge control circuit 110 works as discharge circuit of the present utility model, constitutes corresponding to the WD signal of periodically inputting when microcomputer 201 regular event, makes capacitor 202 discharges.That is, only limit in the situation of microcomputer 201 regular event state continuances, capacitor 202 periodically discharges and recharges.

Signal output apparatus 130 constitutes, and reaches in the charging voltage of capacitor 202 in the situation of setting to export reset signal.If microcomputer 201 is because of the former thereby malfunction such as out of control, then the WD signal is not exported.Therefore, owing to capacitor 202 does not discharge, so only from the electric current supply continuation of charge-discharge control circuit 110, the charging voltage of capacitor 202 rises.Charging voltage reaches the situation of setting, represents that the WD signal is judged the unusual condition of microcomputer 201 accordingly not to charge-discharge control circuit 110 inputs within a certain period of time.

Input to microcomputer 201 from the reset signal of signal output apparatus 130 outputs.Microcomputer 201 is carried out reset processing according to this input, if there is not other special problem, recovers the regular event state.Therefore the WD signal is exported again, and the periodicity that repeats above-mentioned capacitor 202 discharges and recharges.

Fig. 2～4th is for the figure of the action that the monitoring arrangement 100 that present embodiment relates to is described.Specifically describe above-mentioned action with reference to Fig. 2.

If ECU 100(microcomputer 201 starting, then during after T1 carries out the initial stage charging and discharging action of capacitor 202, charge-discharge control circuit 110 begins charging.The output of signal output apparatus 130 is fixed on H logic current potential.If microcomputer 201 is finished start up process, then begin the output of WD signal.The WD signal is the pulse signal that H logic current potential and L logic current potential are periodically repeated.

Charge-discharge control circuit 110 detects the decline of WD signal and discharges, until the charging voltage of capacitor 202 reaches till the V0.If discharge finishes, then receive from the electric power of charge-discharge control circuit 110 and supply with, the charging voltage of capacitor 202 rises again.Because the current potential of WD signal periodically descends, so the discharge of charge-discharge control circuit 110 and the repetition of charge cycle ground (during T2).

If microcomputer 201 is because of out of control etc. former thereby be in the malfunction state, then the output of WD signal disappears (during T3).If owing to do not input the WD signal then capacitor 202 does not discharge, so the electric current that reason charge-discharge control circuit 110 is supplied with and the charging voltage of capacitor 202 continues to rise.

If the charging voltage of capacitor 202 reaches setting V2, then signal output apparatus 130 is exported reset signals (output becomes L logic current potential), and utilizes charge/discharge control circuit 110 to carry out the discharge of capacitor 202, until charging voltage becomes V1.If the charging voltage of capacitor 202 drops to V1, then the output of signal output apparatus 130 returns to H logic current potential.If discharge finishes, then again begin the charging of charging and discharging control circuit 110.

The output of signal output apparatus 130 is with not shown the RESET input electrical connection of microcomputer 201.Microcomputer 201 constitutes, and carries out reset processing when the current potential of reseting terminal becomes L logic current potential.

In example shown in Figure 2, even utilize signal output apparatus 130 output reset signals, microcomputer 201 does not return to the regular event state yet, therefore, can not restart the output of WD signal.Therefore, the charging voltage of capacitor 202 reaches setting V2 again.Therefore, again carry out the output of reset signal by signal output apparatus 130.Until discharge circuit 120 detects till the input of WD signal, repeat this action.

As shown in Figure 1, the electric current that charge-discharge control circuit 110 is supplied with, the resistance value by the terminal 101 external resistance that are connected 102 that have with monitoring arrangement 100 generates usually.If because of beyond thought vibration, impact or aging etc., the connection that terminal 101 is connected with resistance is insufficient, then above-mentioned monitoring arrangement 100 actions can be undesired sometimes.

Fig. 3 represents following example: at moment t1, the connection that terminal 101 is connected with resistance is insufficient, can't guarantee the electric current that charge-discharge control circuit 110 is supplied with to capacitor 202.That is, before moment t1, carry out discharging and recharging of above-mentioned capacitor 202, but constantly after the t1, stop from the electric current supply of charge-discharge control circuit 110, so the charging voltage of capacitor 202 becomes V0.

To this charging source bad danger do not take in the situation of any countermeasure, even do not export because of the WD signal that waits out of control of microcomputer 201, capacitor 202 charging voltages also can be V0, so signal output apparatus 130 can't be exported reset signal.Shown in Fig. 3, at the former moment t2 that should export reset signal, the output of signal output apparatus 130 still is H logic current potential.

As shown in Figure 1, the monitoring arrangement 100 of present embodiment has rapidly charging circuit 140.Charging circuit 140 constitutes rapidly, if detecting the electric current supply that comes from charge-discharge control circuit 110 stops, then by 2nd path 141 different from the 1st path 111, supply with 2nd electric current I 2 larger than the 1st electric current I 1, thereby capacitor 202 is charged rapidly.

More particularly, charging circuit 140 constitutes rapidly, supplies with the electric current of following degree to capacitor 202: can within the time shorter than the input cycle of WD signal, make charging voltage reach setting V2.

As shown in Figure 4, if at moment t1, terminal 101 is insufficient with being connected of resistance 102, and 202 electric current supply stops from charge-discharge control circuit 110 to capacitor, and then charging circuit 140 beginnings are charged rapidly to capacitor 202 rapidly.Therefore, the charging voltage of capacitor 202 rises rapidly, reaches setting V2 at moment t3.Therefore, signal output apparatus 130 can be exported reset signal.

According to this structure, at charge-discharge control circuit 110 abnormals and in the situation that capacitor 202 can't charge normal, by the path different from the electric current supply path of charge-discharge control circuit 110 capacitor 202 is charged rapidly, make forcibly signal output apparatus 130 output reset signals.Therefore can avoid following situation: in the non-existent while of WD signal, because unusual capacitor 202 charging voltages of charge-discharge control circuit 110 do not reach setting V2, can't detect microcomputer 201 unusually.Therefore, can provide the fail safe performance higher monitoring arrangement.

In addition, become following structure, that is, the 2nd electric current I 2 makes the charging voltage of capacitor 202 reach setting V2 within the time shorter than 1 cycle of WD signal.Therefore, even in the simultaneous situation of unusual contingency of the fault of charging circuit 110 and microcomputer 201, also can avoid to judge the unusual of microcomputer 201.

Owing to preferably in the impaired situation of charge function, do not restart microcomputer 201, therefore in the present embodiment, do not carry out the discharge of the capacitor 202 that charged rapidly, keep charging voltage V2.Therefore, the output of signal output apparatus 130 continues to keep L logic current potential, and microcomputer 201 becomes halted state.Under this situation, certainly give the alarm and to user notification, monitoring arrangement 100 is placed under repair or changes.

That is, by keeping the pressure output state of reset signal, can notify the fault of charge-discharge control circuit 110.Owing to can avoid under the state of charge-discharge control circuit 110 faults, restarting microcomputer 201, therefore can provide the ECU 200 with higher fail safe performance.

Below, with reference to Fig. 5, the concrete circuit structure that is used for realizing above-mentioned action is described.In addition, below use the term of " connections " of circuit diagram explanation, only otherwise specify that all expression is electrically connected, so long as physical connection, no matter connected directly or indirectlyly all can.

Monitoring arrangement 100 has terminal 101,103,104,105.One end of above-mentioned resistance 102 is connected with terminal 101, other end ground connection.One end of capacitor 202 is connected with terminal 103, and the other end is connected with power supply.Terminal 104 is that input is from the input terminal of the WD signal of microcomputer 201.Terminal 105 is that output is from the lead-out terminal of the reset signal of signal output apparatus 130.

Monitoring arrangement 100 has internal circuit 150.Internal circuit 150 has reference voltage generating unit 160 and current stops test section 180.

Reference voltage generating unit 160 has reference voltage source 161, operational amplifier 162, transistor 163 and transistor 164.The positive side differential input terminal sub-connection of reference voltage source 161 and operational amplifier 162.Transistor 163,164 is respectively NPN transistor.The lead-out terminal of operational amplifier 162 is connected with transistor 163,164 base terminal respectively.Minus side differential input terminal of operational amplifier 162 respectively with transistor 163,164 emitter terminal sub-connection.Transistor 163,164 emitter terminal are connected with terminal 101.

The collector terminal of transistor 164 is connected with charge-discharge control circuit 110.The resistance value of the magnitude of voltage of reference voltage source 160 and external resistance 102 is set as, between each collector electrode of the transistor 164 that is in on-state, emitter, and can be from charge-discharge control circuit 110 current flowing I1.Charge-discharge control circuit 110 is connected with terminal 103 via the 1st path 111, supplies with the 1st electric current I 1(to capacitor 202 and is designated hereinafter simply as electric current I 1).Capacitor 202 is accepted the supply of electric current I 1 and is recharged.At this moment, internal circuit 150 works as charging circuit of the present utility model.

The value of electric current I 1 is set as, so that be not discharged, continue the time till the charging voltage of the capacitor 202 of rising reaches setting V2 owing to there is not the WD signal, exists the unusual time corresponding with judging microcomputer 201.That is, the value of electric current I 1 is set as, and makes the charging voltage of capacitor 202 reach setting V2 through time in 1 cycle surpassing at least the WD signal.

Internal circuit 150 also has the transistor 171 as PNP transistor.The emitter terminal of transistor 171 and collector terminal respectively with the collector terminal sub-connection of power supply and transistor 163.The base terminal of transistor 171 is connected with the collector terminal of self and the base terminal of the transistor 181 that has of current stops test section 180.

Current stops test section 180 has above-mentioned transistor 181, resistance 182, resistance 183 and transistor 184.Emitter terminal as the transistor 181 of PNP transistor is connected with power supply.The collector terminal of transistor 181 is connected with the base stage of transistor 184 and an end of resistance 182.The other end ground connection of resistance 182.One end of resistance 183 is connected with power supply, the other end and collector terminal sub-connection as the transistor 184 of NPN transistor.The emitter terminal ground connection of transistor 184.

Internal circuit 150 also has not gate 191, transistor 192 and resistance 193.The collector terminal sub-connection of the other end of the input terminal of not gate 191 and resistance 183 and transistor 184.The lead-out terminal of not gate 191 is connected with base terminal as the transistor 192 of PNP transistor.The emitter terminal of transistor 192 is connected with power supply, and collector terminal is connected with resistance 193.The other end of resistance 193 is connected with terminal 103.

Current flowing I1 between the collector electrode of transistor 164, emitter terminal and when carrying out the charging of capacitor 202, current flowing I1 between the collector electrode of transistor 163, emitter terminal, accompany with it also current flowing I1 between the emitter of transistor 171, collector terminal.

Transistor 171 and transistor 181 form so-called current mirroring circuit.Therefore, current flowing I1 between the emitter of transistor 171, collector terminal, thereby between the emitter of transistor 181, collector terminal also current flowing I1.

By current flowing I1 between the emitter of transistor 181, collector terminal, transistor 184 becomes on-state.Therefore the output of not gate 191 becomes H logic current potential, and transistor 192 becomes off-state.Therefore from transistor 192 via resistance 193 until can current flowing the path of terminal 103.

For example, at the dockingundocking of terminal 101 with external resistance 102, or in the situation of terminal 101 power supply short circuits (and short circuit between power supply), can current flowing I1 between the collector electrode of the transistor 164 of reference voltage generating unit 160, emitter terminal, can't be by electric current I 1 to capacitor 202 chargings.

At this moment, also current flowing I1 not between the collector electrode of transistor 163, emitter terminal, transistor 171 becomes off-state.Utilize the current mirror action, the transistor 181 of current stops test section 180 becomes off-state, accompanies with it, and transistor 184 also becomes off-state.

Therefore, the output of not gate 191 becomes L logic current potential, and transistor 192 becomes on-state.Between the emitter of transistor 192, collector terminal, flow through the 2nd electric current I 2(and be designated hereinafter simply as electric current I 2), supply with to capacitor 202 via the 2nd path 141.Capacitor 202 is accepted the supply of electric current I 2 and is recharged.Electric current I 2 is electric currents larger than electric current I 1, is set as the value that the charging voltage that can make capacitor 202 within the time shorter than 1 cycle of WD signal reaches setting V2.

Namely, internal circuit 150 has by the supply that stops electric current I 1 to be become the transistor 184 of off-state and becomes off-state and it becomes the transistor 192 of on-state by this transistor 184, become on-state by transistor 192, supply with electric current I 2 to capacitor 202.Therefore, at this moment internal circuit 150 works as charging circuit 140 rapidly.

Signal output apparatus 130 is connected with terminal 103, constitutes the charging voltage that can monitor capacitor 202.Signal output apparatus 130 is connected with terminal 105 in addition.Reach setting V2 if detect charging voltage, then signal output apparatus 130 is from terminal 105 output reset signals.Reset signal inputs to microcomputer 201.

Below with reference to Fig. 6, the 2nd example for the circuit structure of realizing action of the present utility model is described.For having the inscape of identical or suitable function with internal circuit 150 shown in Figure 5, mark equally with reference to label, the repetitive description thereof will be omitted.

The internal circuit 150A that this example relates to, the structure of current stops test section 180A is different from the structure of the current stops test section 180 of internal circuit 150.Current stops test section 180A has transistor 181, resistance 182, resistance 185, comparator 186 and reference voltage source 187.

Replace the transistor 171 of internal circuit 150, an end of resistance 185 is connected with power supply.The other end of resistance 185, the collector terminal of the transistor 163 that has with reference voltage generating unit 160 and the base terminal of transistor 181 are connected.

The positive side differential input terminal sub-connection of the collector terminal of transistor 181 and comparator 186.The minus side differential input terminal sub-connection of reference voltage source 187 and comparator 186.The not gate 191 that internal circuit 150 has is not set, and the lead-out terminal of comparator 186 is connected with the base terminal of transistor 192.

When supplying with electric current I 1 to capacitor 202, as mentioned above, current flowing I1 between the emitter of transistor 181, collector terminal.Accompany with it, the collector terminal current potential of transistor 181 rises, and the current potential of positive side differential input terminal of comparator 186 is higher than the current potential of reference voltage source 187.Its result, comparator 186 outputs become H logic current potential, and transistor 192 becomes off-state, is passing through resistance 193 until can current flowing I2 in the path of terminal 103.

On the other hand, if since the fault etc. in the terminal 101 and between the collector electrode of transistor 164, emitter terminal current flowing I1 not, then transistor 163 becomes off-state, thus between the base stage of transistor 181, emitter terminal current flowing not, transistor 181 becomes off-state.

Accompany with it, the collector terminal current potential of transistor 181 descends, and the current potential of positive side differential input terminal of comparator 186 is lower than the current potential of reference voltage source 187.Its result, the output of comparator 186 becomes L logic current potential, and transistor 192 becomes on-state.Capacitor 202 is received in the electric current I 2 that flows through between the emitter, collector terminal of transistor 192 and is charged rapidly.

Below with reference to Fig. 7, the 3rd example for the circuit structure of realizing action of the present utility model is described.For having the inscape of identical or suitable function with internal circuit 150 shown in Figure 5, mark identically with reference to label, the repetitive description thereof will be omitted.

The internal circuit 150B that this example relates to, the structure of its current stops test section 180B is different from the structure of the current stops test section 180 of internal circuit 150.Current stops test section 180B has transistor 181, resistance 183, transistor 184, constant-current source 188, transistor 189 and transistor 190.

The collector terminal of transistor 181 is with the base terminal of transistor 184 and as the collector terminal sub-connection of the transistor 189 of NPN transistor.The emitter terminal ground connection of transistor 189.

Constant-current source 188 is supplied with the electric current I 3 less than I1.One end of constant-current source 188 is connected with power supply, the other end and collector terminal sub-connection as the transistor 190 of NPN transistor.

The collector terminal of transistor 190 is connected with base terminal, emitter terminal ground connection.In addition, connect between the base terminal of transistor 190 and transistor 189.That is, transistor 189 and transistor 190 form current mirroring circuit.

The electric current I 3 of being supplied with by constant-current source 188 flows through between the collector electrode of transistor 190, emitter terminal.Utilize current mirror action, also current flowing I3 between the collector electrode of transistor 189, emitter terminal.

When supplying with electric current to capacitor 202, as mentioned above, current flowing I1 between the emitter of transistor 181, collector terminal.Therefore, current flowing in the base terminal of transistor 184 (I1-I3), transistor 184 becomes on-state.Be the value that the value of electric current I 3 is set as following degree: so that electric current (I1-I3) can make transistor 184 become on-state.

Therefore the output of not gate 191 becomes H logic current potential, and transistor 192 becomes off-state.Therefore, from transistor 192 via resistance 193 until can current flowing I2 the path of terminal 103.

On the other hand, if because the fault of terminal 101 etc., current flowing I1 not between the collector electrode of transistor 164, emitter terminal, then transistor 163 becomes off-state, thereby current flowing not between the base stage of transistor 181, emitter terminal, transistor 181 becomes off-state.

Accompany therewith, the electric current that flows through in the base terminal of transistor 184 is for (I3), transistor 184 becomes off-state.Its result, the output of not gate 191 becomes L logic current potential, and transistor 192 becomes on-state.Capacitor 202 be received in transistor 192 emitter, the electric current I between collector terminal 2 supply and charged rapidly.

Above-mentioned execution mode is in order more easily to understand the utility model, is not to limit the utility model.The utility model can not break away from change, the improvement of its purport, and comprises its equivalent in the utility model, and this is very clear and definite.

By make the time till charging voltage reaches setting V2 to capacitor 202 supply electric current I 2, it might not be the time shorter than 1 cycle of WD signal.Prolong the charging interval in the scope that can not exert an influence at the abnormal state determination to microcomputer 201.Can relax thus the rapidly design condition of charging circuit 140.

The signal of signal output apparatus 130 outputs might not be the signal be used to the microcomputer 201 that resets.Also can be used to the signal that makes microcomputer 201 carry out other actions, or be used for the signal of the fault of notice charge-discharge control circuit 110.

By the object of monitoring arrangement 100 supervision operate conditions, be not limited to the microcomputer 201 of ECU 200.Get final product so long as can export the device of the control signal suitable with the WD signal, can be with suitable control device as monitored object.

Claims (8)

1. monitoring arrangement, its operate condition to control device monitor,

It is characterized in that having:

Charging circuit, it supplies with the 1st electric current by the 1st path, and capacitor is charged;

Discharge circuit, it is corresponding to the supervisory signal of periodically inputting from control device, to described discharging capacitors;

Signal output apparatus, its charging voltage at described capacitor reaches in the situation of setting, the non-existent signal of the output described supervisory signal of expression; And

The forced charge circuit, it by 2nd path different from described the 1st path, supplies with 2nd electric current larger than described the 1st electric current in the situation that the supply that detects from described the 1st electric current of described charging circuit stops, described capacitor is charged.

2. monitoring arrangement according to claim 1, wherein,

Described forced charge circuit makes the charging voltage of described capacitor reach described setting within the time shorter than the input cycle of described supervisory signal.

3. monitoring arrangement according to claim 1 and 2, wherein,

Described forced charge circuit has: the 1st transistor, and when the supply of described the 1st electric current stopped, the 1st transistor became off-state; The 2nd transistor, when described the 1st transistor became off-state, the 2nd transistor became on-state,

When described the 2nd transistor becomes on-state, supply with described the 2nd electric current to described capacitor.

4. monitoring arrangement according to claim 3, wherein,

Described forced charge circuit has comparator, when it becomes off-state at described the 1st transistor, makes described the 2nd transistor become on-state.

5. monitoring arrangement according to claim 3, wherein,

Described forced charge circuit has constant-current source, and when the supply of described the 1st electric current stopped, this constant-current source made described the 1st transistor become off-state.

6. the described monitoring arrangement of any one in 5 according to claim 1, wherein,

Described the 1st electric current is generated by the external resistance that is connected with described charging circuit.

7. vehicle-mounted type electronic-controlled installation,

It is characterized in that having:

Microcomputer;

Capacitor;

Charging circuit, it supplies with the 1st electric current via the 1st path, and described capacitor is charged;

Discharge circuit, it is corresponding to the supervisory signal of periodically inputting from described microcomputer, to described discharging capacitors;

Signal output apparatus, its charging voltage at described capacitor reaches in the situation of setting, the non-existent signal of the output described supervisory signal of expression; And

The forced charge circuit, it by 2nd path different from described the 1st path, supplies with 2nd electric current larger than described the 1st electric current in the situation that the supply that detects from described the 1st electric current of described charging circuit stops, described capacitor is charged.

8. vehicle-mounted type electronic-controlled installation according to claim 7, wherein,

Described signal is the signal that described microcomputer is resetted,

The charging voltage that described rapidly charging circuit is kept described capacitor reaches the state of described setting.

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