Perpetual motion energy of (GOD) on countenance entry and motor starting in a vehicle

Perpetual motion energy defining two 12 V DC batteries, two DC-AC converters, and two DC-AC adaptors for connecting, therewith the converters, and the batteries, each battery is located in a conventional battery charger, such that both of the batteries define fully charged operating current thereby to charge one another until two relays open duplex circuits. Two cartridges containing restorable properties for extended perpetual battery life are provided, and are drained therein each battery, whenever, operating voltage levels are low. A countenance entry system, outwardly on a door is provided to turn on a vehicle's motor, activate a heater, a hood opener, a trunk opener, a power window, and offers legal entry via a video recorder recording a user's face as each switch is on.

DESCRIPTION OF THE PREFERRED EMBODIMENTS Referring to FIG. 1 , dual conventional battery chargers H 1 -H 2 charges one another, as two LEDs Ra and Rb glow on the chargers. This charger H 1 uses a battery B 1 , as the charger H 2 defines a battery B 2 of a Perpetual Motion Energy system. Electrochemical at which oxidation occurs in these cells are complex alloys, thus containing many metals such as an alloy of V, Ti, Zr, Ni, Cr, Co, and (&excl;) Fe. A plug P 1 of a DC-AC converter V 1 fits an output outlet O 1 on the charger H 1 . A DC-AC converter V 2 has a plug P 2 in an output outlet O 2 upon the charger H 2 . This system causes each 12 V battery to charge one another, as an AC adapter A 1 fits a charger jack 1 by a male plug M 1 upon the charger H 1 . As the adapter part A 1 plugs in the converter V 2 the battery B 2 outputs current that charges the battery B 1 . Now this is done, as an AC adapter A 2 fits a charger jack C by a plug M 2 on the charger H 2 , the adapter A 2 plugs in the converter V 1 . Now when the battery B 1 is charging the battery B 2 , the output outlet O 1 upon the charger H 1 outputs 12 V DC current by which the converter V 1 converts into alternating current. The current flows through this adapter A 2 , its lead, and the plug M 2 via the charger jack C. This charges the battery B 2 whereby, the battery B 2 is likewise charging the battery B 1 . Two relays R 8 , and R 9 prevent both batteries B 1 -B 2 from overcharging, as these LEDs Ra-Rb glow as each battery B 1 to B 2 chargers each other. Two LEDs Gr-Hr glow as each battery B 1 -B 2 endures a full charge. As the LEDs Gr-Hr and two LEDs RE-SE glow compatibly, each battery B 1 -B 2 is satisfactorily, defined as being charged. Yet, each relay R 8 -R 9 engages its contacts to close each charging circuit C 1 -C 2 , as this also, defines that each battery B 1 -B 2 must be, eventually charged. The batteries B 1 -B 2 charge one another, so, a full charge is done, two LEDs F-g emit light. These batteries B 1 -B 2 charge one another to sustain a full charge, even, when an electric motor M of a vehicle V is turned off, as shown in FIG. 3 . While each battery in each circuit uses the same amount of voltage, each circuit induces the same amount of current. This causes the batteries B 1 -B 2 to charge one another, until each relay R 8 , and R 9 opens the charging circuits C 1 , and C 2 with respect to disengagement of their contacts. As shown in FIG. 2 , the DC-AC converter V 1 is connected to the charger H 1 , as the DC-AC converter V 2 is connected to the charger H 2 , each battery B 1 -B 2 charges one another as an end of the AC adapter A 1 is connected to the charger H 1 . As the AC adapter part A 1 is plugged into the converter V 2 , the battery B 2 outputs current that charges the battery B 1 . Now this is done as a lead of the adapter A 2 is connected to the charger H 2 , since its adapter portion A 2 is plugged into the converter V 1 . The relays R 8 to R 9 are connected to an input terminal of the converters V 1 -V 2 . The LEDs Gr-SE emit light as each battery B 1 -B 2 requires charging, all LEDs Ra-Rb, Gr, RE, Hr, SE, F, and g are connected via the other terminal of the converters V 1 -V 2 . The LEDs F-g glow, while each battery B 1 to B 2 is, fully charged by (PME) perpetual motion energy. Referring to FIG. 3 , this PME system is disposed in the vehicle V under a hood H, as the charger H 1 , and its battery B 1 fit in a battery box B, the charger H 2 and its battery B 2 fit a battery box B 3 . A Polarized plug Z via the motor M is plugged in this DC-AC converter V 1 . Besides, the embodiment about the PME system is such that alternators will function, conventionally since this system charges itself perpetually. As PME electric vehicles exclude gas tanks, two several hundred ton batteries can provide PME the same as FIGS. 1 - 3 . The PME system outputs current for charging each battery for ten years. As shown via FIGS. 4 - 4 B, a LED 0 glows about two battery cartridges 98 - 99 after 9 years and roughly 9 months. A user has 3 months to return both battery cartridges 98 - 99 . As the life of a prime battery is five years, each cartridge 98 to 99 restores its battery's voltage to a, fully, charged operating level for another five years. E.g., as this LED 0 emits light by its AC, or DC current-limiting resistor about a dashboard ( FIG. 9 ), a gear motor GM having a gear MG about a shaft 38 is actuated by a CMOS op amp (IC 1 ), which is used as a voltage comparator. This scans the levels of two input voltages and turns its output on or off based on which input voltage is, more. The input via pin 2 is set to a reference voltage of almost half the supply voltage by R 3 -R 4 , when the input on pin 3 is connected to a voltage divider R 1 , and one potentiometer R 2 . The resistance of a photocell changes, as the LED 0 emits light, the light intensity is, indicatively, shown by the voltage on pin 3 of IC 1 . The light level which turns on the circuit is fixed by R 2 . The output of pin 6 is turned on by R 5 , when the voltage about pin 3 of IC 1 is more than pin 2 , the output of IC 1 drives a transistor Q 1 so this transistor Q 1 turns the motor GM on, and off via the op amp. Referring to FIGS. 4 - 4 B, as the LED 0 starts this motor GM, the motor gear MG is rotated clockwise, so, as to rotate an Electrolyte gear EG, and a Sulphuric Acid gear AG counter clockwise. This is performed simultaneously, since the gear MG is placed between both gears EG, and AG, so that two cone shaped plugs 1 M- 2 M are rotated upwardly from two drain holes 39 - 40 . The plugs 1 M- 2 M are secured below two helixes 41 - 42 . Two perforated blocks jj-kk using internal screw threads for receiving each helix 41 - 42 . The gear EG is secured upon the helix 41 , and the gear AG is secured upon the helix 42 . The cartridges 98 - 99 have two tubs, namely, EL and SA. The tubs EL, and SA are divided via two walls 4 Z- 5 Z, as a nonmetallic electric conductor Electrolyte in which current is, thereby, carried on an atom as ion, or the movement of ions, occupies the tub EL. As the atom ion carries a positive, or negative electric charge, this is a result of having lost, or, gained one or more electrons. Electrolyte is a substance that when dissolved in Sulphuric Acid becomes a fused ionic conductor. Accordingly, the Sulphuric Acid occupies the tub labeled SA. As both floor surfaces 49 - 50 define an acute angle, the Electrolyte, and the Acid will drain smoothly, via the drain holes 39 - 40 . This generates the voltage in the batteries B 1 and B 2 to a fully charged voltage status about modification. As shown in FIG. 1 , each cartridge 98 - 99 is to extend by way of a cutout 3 B- 3 C of the chargers H 1 -H 2 . The lower portions of the cartridges 98 - 99 will fit two battery cutouts 5 C- 6 C. Referring to FIGS. 5 - 6 , the vehicle V has a Face and/or Countenance Entry system, so, as a user pushes a first water proof unit switch 6 a located upon one outer door Do, a first computerized video recorder RR is actuated. The recorder RR records a user's face when a user views a mirror-like shield S 1 . Such countenance, and/or face shield S 1 lets a video be generated through its central transparent surface 65 . Since the recorder RR is fixed perpendicularly below the shield S 1 in the driver's door Do, the recorder RR records the face of a user, while the switch 6 a is actuated to gain legal entry. Since a first input system has countenance or face data inputted optically, to become computer data, or a signal via an image sensor, a face, or countenance signal is outputted, as a LED 1 b illuminates the shield S 1 . The recorder RR uses a white balance system for illuminating the face input to be recorded, also. This video recorder RR is made up of a lens ZZ, as the sensor is a pickup device, which views this input so, as to change it into the face signal, a receiving system 27 - 29 receives this face signal from a transmitter 48 . As a focusing system measures the distance below this face shield S 1 , as emitting infrared rays, detects bona-fide face input, when the shield S 1 is viewed, as a pushbutton 68 is pressed. Infrared rays via an infrared light emitting is shot through a protecting lens to the face input. The input is hit while the rays reflect back using a receiving lens as entering the sensor. Since the sensor includes two photodiodes, a signal processing control system moves the receiving lens, so as to equalize the light intensity of the two photodiodes. When a drive pulse generator circuit generates pulses to drive this image sensor by a signal-processing circuit, the face signal is outputted, as the face input is inputted using any switch and the shield S 1 . While the sensor picks up the input, and feeds it to the processing circuit, outputs the face signal. The first unit switch 6 a is thus actuated by way of the pushbutton control 68 , such as to provide countenance entry. Now a second unit switch 7 a is actuated when its countenance pushbutton control 69 is thus pushed upon the outer door Do, switches on the vehicle's motor M via the countenance input. As the transmitter 48 , and the recorder RR are actuated compatibly, an actuator 2 b actuates a push-button 3 b of this transmitter 48 , as each button 68 - 69 pushes the actuator 2 b . The transmitter 48 stores the face and/or countenance signal in its countenance memory 21 , while the shield S 1 is viewed. The transmitter 48 , and the recorder RR are fixed in the door Do and defined as the input system including the shield S 1 . The control 69 which turns on the motor M is below, the shield S 1 whereby adjacent to the control 68 , two door-locks are freed, and the motor M is turned on even before the door Do is opened, when each switch 6 a - 7 a is activated by a user. Referring to FIG. 6 , the transmitter 48 has one antenna 26 to receive, and transmit radio signals by three receiving antennas 27 - 29 as a central processing unit CPU 90 controls. The transmitter 48 has the face signal memory 21 , a modem 24 to serve, as a demodulator via received unit signals, and is to generate output signals of which are transmitted via face data input regarding the face, and/or countenance signal. A unit signal detector 25 is to detect the unit signals demodulated in the modem 24 . A countenance signal generator 22 is for receiving the face signal, which proceeds from the countenance signal memory 21 . The countenance signal is now outputted from the countenance signal generator 22 up to the modem 24 , subsequently to any unit signal being so detected. Lastly, a dispatcher oscillator 23 is to output a dispatcher signal due to the course of the countenance signal, thereby, being transmitted with respect to the transmitter 48 . A controller 60 in the vehicle V has the antennas 27 to 29 to transmit, and receive radio signals by the transmitter 48 . A modem 31 demodulates signals received, yet, generates output signals to be transmitted to the transmitter 48 . The system by which the unit signals are transmitted relies upon the receiving system, i.e., the three antennas 27 , 28 to 29 . As an oscillator 400 is provided to output a dispatcher signal, the CPU 90 is to control a face system, and a memory 37 is to store a preset face, and/or countenance signal. As the face signal matches the preset face signal such as to be decided by the CPU 90 , a transistor Q 3 is triggered. A coil of a relay Y is hot as the transistor Q 3 is triggered. This relay Y is, also, connected to many automotive devices, as a door-lock device, one trunk opener, power windows, a heater, a hood opener, and a steering lock device. A coil 45 via an actuator is for freeing a door-lock of a user's seat section yet, a coil 44 of an actuator is for freeing a door-lock via a commuter seat section, since the steering locks by a timer only, as the vehicle is parked. A coil 46 of an actuator is to cause the LED 1 b to illuminate this face input shield S 1 . As the relay Y is hot, the door-locks are freed, and the LED 1 b is actuated by the switch 6 a , since the unit switch 6 a is connected to the input terminal of the CPU 90 . Besides, the CPU 90 will compare the tracing extremity of this input face signal generated, as the unit switch 6 a activates this video recorder RR, whereby a resistor R 6 is provided. As shown in FIG. 7, a step-by-step flow-chart is added. Step 1 , the unit switch 6 a is activated, when the input shield S 1 is inputted with real countenance data via a legal user, as the control 68 is pushed, incorporates legal entry Step 2 , the unit signal is transmitted via the antennas 27 - 29 to the antenna 26 that is found in the transmitter 48 . The transmitter 48 , and the recorder RR are turned on by the buttons 68 - 69 actuating the unit switches 6 a - 7 a . Since this unit signal is received by the antenna 26 of the transmitter 48 , this unit signal detector 25 detects the unit signal, so that the face signal is analyzed from the face signal memory 21 , however, to the face signal generator 22 . Step 3 , when the face signal is outputted by the signal generator 22 and through the modem 24 , the modem 24 receives a dispatcher wave generated by the dispatcher oscillator 23 . This face signal is covered by the dispatcher wave to form a radio signal since the face signal travels on the dispatcher wave. When the modem 24 transmits the face signal by way of the antenna 26 to these antennas 27 - 29 , the preset signal is programmed out from the countenance memory 37 to the CPU 90 . Step 4 , the CPU 90 utilizes the memory 37 , and compares the countenance signal thereby the preset countenance signal from the transmitter 48 , whereby through the antennas 27 - 29 . Step 5 , when the countenance signal so matches with the preset countenance signal, the transistor Q 3 is activated in step 6 , as the relay Y is hot such that the current flows by way of the coils 44 , 45 , 46 , and the LED 1 b . As a rule, the door-locks are freed, as this LED 1 b emits light. Now, when a match is not, decisively defined by the CPU 90 about these countenance signals, the face system returns to its starting status. When a user's true countenance is recorded via this shield S 1 while the switch 6 a is actuated, unlocks this door Do in step 7 . This will allow legal entry for a legal user. Step 8 , the transistor Q 3 is deactivated via the timer, which is setoff to start timing a prearranged time when such prearranged time has ended, which is, roughly, 25-30 seconds in step 9 . Now the LED 1 b and the actuators are deactivated also. The steering lock is released, only, as face input is inputted as the switch 7 a is actuated, turns on the motor M. Step 10 , the CPU 90 outputs a commandment signal as the countenance signal matches the preset signal which is stored in this memory 37 . The vehicle V will now be referred to as Moses with respect to a reference name regarding this unique invention, which was granted to applicant from GOD ALMIGHTY. As shown in FIGS. 8 - 8 A, the motor M indeed, incorporates the Polarized plug Z. The recorder RR being defined by an (ADA) adaptor which will be connected to a DC source, as an output cable 1 d is connected to the input terminal of the CPU 90 . Thus, the recorder RR can be operated from this ADA, or will charge up its batteries, as the face input is inputted, since the perpetual DC supply voltage of Moses is lowered or thereby, raised according to the operating voltage about the recorder RR. Since the switch 7 a is connected about the CPU 90 , the antennas 27 - 29 will transmit the unit signal to this transmitter 48 , as a user activates the unit switch 7 a while viewing the countenance shield S 1 simultaneously. This will cause the motor M to be turned on by the commandment signal, since the transmitter 48 thereby, answers the unit signal by transmitting the countenance signal. A resistor R 7 is provided via the switch 7 a , and in the same manner as set forth above by modification, a transistor Q 4 is provided also. As a rule, the motor M is only, turned on when a match is determined by the CPU 90 , seeing that the transistor Q 4 is for turning on the motor M regarding Moses, when a relay MR is hot. As a result, the commandment signal is outputted, whereby, the electric current concerning Moses flows through a coil via this relay MR about the prearranged time of the modification. Thus, the transistor Q 4 is turned off, such that the operation returns to a starting position. This transistor Q 4 is engineered to turn on the motor M of Moses, when the foundations of the transistors Q 3 , and Q 4 are connected to the output terminals about the CPU 90 . The adjacent transistor Q 3 is for freeing both door-locks, since this motor M, and all accessories regarding one clock, power windows, a radio, or the like are actuated as the transistor Q 4 is turned on, and the coil of the relay MR is hot. The collector of this transistor Q 3 is connected to the hot coil of this relay Y, and to a collector bias source Vcc of the CPU 90 . The emitter of the transistor Q 3 is grounded as an end of these coils 44 , and 45 of actuators for freeing the door-locks is connected to a lead via the collector bias source Vcc, the other end is grounded through the relay Y. As the transistor Q 3 is actuated, the coil of the relay Y is hot, such that electric current flows through the coils 44 and 45 that unlocks the doors of Moses. The collector of this transistor Q 4 is connected to the coil cf the relay MR, and the collector is connected via the collector bias source Vcc. The emitter of this transistor Q 3 is grounded, and one lead of the coil 46 of actuator, such, as to cause the motor M to be turned on is connected to this collector bias source Vcc, while the other leads are grounded using this relay MR. The LED 1 b is connected about the collector bias source Vcc, and the other leads are grounded through this relay MR. Since this transistor Q 4 is turned on from legal countenance input and a match is determined, the coil of the relay MR is hot, so that electric current flows through the coil 46 , and the LED 1 b . The motor M of Moses is turned on as the switch 7 a is activated by a legal user, the switch 7 a turns off the motor M of Moses, as it is setoff once more by a legal user. 
 Second embodiment Now using new references and above comparable elements. Referring to FIGS. 9 to 10 , a countenance input shield S 2 is adjacent the dashboard, and a motor switch 57 , as its enter, delete, and ACC switches 6 , 7 , and A are for thus, operating as follows: the face input pushbutton shield switch 57 turns on a second video recorder J (not shown), whereby located in the dashboard of Moses for changing optical information into computer data, turns on this motor M. This face input enter switch 6 is for entering data of a transit user, as the face delete switch 7 is to delete the data of a transit user, the ACC A switch actuates the accessories that are controlled by a user's face. When such face is recorded by the recorder J through the shield S 2 , while the switches 57 , 6 , 7 and A are operated, each switch will perform its operation compatibly. Referring to FIGS. 11 and 12 , here is a more affordable system, which has a pushbutton motor switch LS. This switch LS includes a face shield S 3 found in the vehicle Moses upon the door Do, so as to input face data optically through this system using the recorder RR. As this motor M is turned on, as set forth above concerning modification, the motor switch LS is setoff while being pushed by a user, so as to activate the recorder RR to turn on the motor M in the sane manner. Generally, the motor switch 57 including the recorder J is excluded from all vehicles defining this LS system, since the input computerized video recorder RR provides face entry and motor starting prudently, regarding the motor switch LS. The input shield S 3 , its enter, delete and ACC switches 6 , 7 , and A are designed so that when each switch is pushed, while the face of a user is recorded through this shield S 3 , each switch is to power its operation via modification. The switch LS is only in vehicles omitting the switch 57 , while this switch 57 is only in vehicles excluding this switch LS. Since Moses comprises a controller 17 about this countenance and/or face input system, such system incorporates ten input switches. One heater push-button switch HS, a window switch WS, a hood switch HO, and a trunk switch TS each of which is upon the outer door Do. E.g., each switch being pushed when a user's countenance is being recorded however, will promote each switch to operate its function simultaneously. Referring to FIGS. 5 and 10 , the door Do includes these four input countenance pushbutton switches HO, TS, HS and WS outwardly, and adjacent to each side of this face shield S 1 , so that the input countenance shield S 1 appears in the midst thereof. E.g., the hood switch HO actuates the hood opener, the switch TS is for triggering the trunk opener, the switch HS is for turning on the heater, while this switch WS is for the window control operations. These switches are operated, before a user opens and enters through the door Do of Moses. Referring to FIGS. 10 and 12 , a countenance video image converter (FVI) converter 14 is for thus, converting signals outputted which are produced while countenance input is, yet inputted through the recorders RR, and J to activate a motor switch 200 including switches HO, TS, HS, WS, 100 , 57 and/or LS, 6 , 7 and A which are ten switches without the switch LS. An OR-gate circuit 15 is so that a logical amount of in put signals are generated from the FVI converter 14 , a video pattern generator 64 comprises a clock for driving a counter change. This addresses a preprogrammed video pattern memory 16 (PVPM) for generating a video waveform. Now this outputs address signals on the output signals from the FVI converter 14 , and the memory 16 . Further, this controller 17 includes a comparator 18 so as to compare all output signals, thereby specifying data from this FVI converter 14 . When all output signals defined by data from this memory 16 are outputted, a high-level logic signal is outputted, also, when this output signal from the FVI converter 14 matches the output from the output signal within the memory 16 . A video negative viewer 32 inverts the video of this countenance input, and produces a negative image on the video of the countenance signal, so, as to match with this output signal from the memory 16 . A D type reset S flipflop circuit 20 is set by the output signal of this video negative viewer 32 . Besides, this outputs the commandment signal, such as to turn on a transistor 47 , as a timer 80 is to thus time a preset time by which the flipflop circuit 20 outputs the commandment signal. Now when the preset time is ended on this timer 80 , the transistor 47 is turned off and a one shot multi-vibrator 61 is actuated. The flipflop 20 is reset via the transistor 47 being turned off, as a retriggerable multivibrator 62 is now actuated in reply to the output signal of the OR-gate 15 . A one-shot multi-vibrator 63 is for outputting a pulse signal, however, of this preset time on the tracing extremity via an output signal of the multi-vibrator 62 . Since this one-shot multi-vibrator 63 resets the video negative viewer 32 , while utilizing this OR-gate 15 , when the preset time is ended, an AND-gate 11 circuit is included for producing an output that is logical. A delay circuit 66 delays the output signal via this AND-gate 11 for the preset time. An OR-gate circuit 67 originates a logical amount of input signals from the output of this one-shot multi-vibrator 63 , thus defining the output of this delay circuit 66 . While the video pattern generator 64 outputs an address signal figurative via this countenance signal, whereby, outputted from the FVI converter 14 and the memory 16 , a high level logic signal is outputted by the AND gate 11 as the delay circuit 66 obtains the high-level logic signal. This is also received by way of the OR-gate 67 , and is done only, when the preset time has ended. Now the video negative viewer 32 is reset when the output signal of the OR gate 67 is outputted. Electric current flows by these coils 44 to 46 , the LED 1 b and a relay 71 , since the transistor 47 answers the output signal from the flipflop circuit 20 . As shown in FIG. 5 B, each face switch 200 -WS and 100 on the outer door Do, which when inputted by way of a user, now activates the hood opener, the trunk opener, the heater, and the window control system, whereby, this LED 1 b emits light. Door-lock actuators are actuated via the switch 100 , thereby a legal user for gaining countenance entry via modification. The countenance input switches are actuated in the dashboard whenever electric current flows using the coils 44 - 46 , also. While the memory 16 comprises a system for storing data of a transit user, when such user pushes the switch 100 and views the face shield S 1 , a legal user operates the face switch 6 . The countenance input each of which becomes computer data by the image sensors, signal circuits and associated components concerning such input. Further, the face data each of which is compared via the comparator 18 , as the output signal from the FVI converter 14 matches the output signal of the memory 16 , a signal of a transit user is stored into the memory 16 . The flipflop circuit 20 outputs the commandment signal after being set by the output signal of this video negative viewer 32 , the commandment signal actuates the time 80 . This timer 80 starts clocking a preset time to delete this data about a transit user, as an image about this data of a legal user is generated alone by the viewer 32 , the input switch 7 deletes the transit data at the preset time which is only 3 seconds. While a user enters Moses, when pushing the switch 100 , the countenance signal is outputted from the recorder RR, so that the FVI converter 14 converts the face signal that goes to the comparator 18 . The signal is now sent through the OR gate 15 , and further to the pattern generator 64 . Since the pattern generator 64 has 43,605 pixels so that each pixel is programmed, a switch provides a choice of custom patterns. Notwithstanding, this generator 64 addresses the memory 16 by an address signal in reply to the face input as a user operates this switch 100 . A preset face signal is outputted from the memory 16 to the comparator 18 . This comparator 18 compares the face signal from the FVI converter 14 with this preset face signal, therefrom the memory 16 . While the face signal matches with the preset face signal, a twofold signal is outputted from the comparator 18 . As this negative image of the face signal matches the preset signal from the memory 16 as the comparator 18 outputs the preset signal, the video negative viewer 32 outputs the commandment signal. Now the commandment signal is outputted to the flipflop circuit 20 , since the flipflop 20 is set on the basis of the commandment signal. As the flipflop 20 outputs a high level signal by a terminal Q to the bed of the transistor 47 , this transistor 47 is turned on as the relay 71 is hot. Electric current flows via the coils 44 - 46 and the LED 1 b . The motor M of Moses is started, as a user's face is recorded when the switch 57 is pushed. The enter and delete switches 6 - 7 , and the dashboard ACC switch A operates only, when the face of a legal user is recorded, while each switch is being operated. When the LED 1 b emits light, after being activated, the timer 80 starts timing the prearranged time, as set forth in the foregoing with respect to modification. Referring to FIGS. 9 , and 10 , one OR-gate circuit 7 v is connected to a terminal S of a flipflop circuit 74 , as these switches 200 -WS are connected via the OR-gate 7 v . While the bases of the transistor 47 and a transistor 36 are connected to an output terminal of an AND-gate 77 , the flip-flop 74 is set by the output signal from the OR-gate 7 v . Besides, this transistor 47 is to free the door-locks while the transistor 36 is for turning on the motor M of Moses, and to setoff the LED 1 b . Since the collectors of these transistors 47 and 36 are connected to a hot coil of this relay 71 , and a coil via a relay 72 , the collectors are connected to a collector bias source Vcc, as the emitter of the transistors 47 , and 36 are grounded. As a lead via the coils 44 to 45 of actuators for freeing these door-locks is connected via the collector bias source Vcc, the other lead is grounded by this relay 71 . As a lead about the coil 46 is connected via the collector bias source Vcc, the other lead is grounded through the relay 72 . Since the output terminal Q of the flipflop 20 , and one output terminal Q to invert this flip-flop circuit 74 , while connected to the two input terminals of one AND-gate 76 , the two input terminals of the AND-gate 77 are connected via the output terminals Q of the flipflop circuits 74 and 20 . Further, the h igh level signals are outputted from this output terminal Q-Q about the flipflop 20 , and 74 to the AND gate 76 , simultaneously while the countenance signal matches via the preset countenance signal in reply to the input face switches 100 , 57 , 6 - 7 , and A. An output signal is outputted from this AND-gate 76 to the transistor 47 , seeing that this transistor 47 is turned on, as the relay 71 is hot. Now the door-locks are freed, as a legal user operates the entry and countenance switch 100 . The switches HO to WS each of which is for performing its operation as set forth above regarding modification of the second embodiment via this construction. While a user's face is recorded when the motor switch 200 is pushed before entering Moses, a user will operate this motor switch LS while seated upon the driver's seat. This is done when the face signal matches with the preset face signal, as these high-level logical signals from the output terminals Q by way of the flip-flop 74 , and 20 are received by two input terminals of the AND-gate 77 . This is also done as an input terminal of the AND-gate 76 , so r e ceives a low level logical signal from this output terminal Q of the flipflop 74 . This AND-gate 77 outputs an output signal to the transistor 36 to turn on the motor M by the face switch 200 . Now this switch LS turns on the motor M of Moses also, using the AND-gate 77 . While this above description contains many specifics of which should not be construed as limitations on the scope of the invention, variations and modifications will be apparent to persons skilled in the art. E.g., the motor M is to have varietal speed switches having a system, so, as to deliver a top speed of 150 mph by a foot pedal FP as shown in FIG. 8B . Two several hundred ton batteries with perpetual energy will provide, such, energy regarding public utilities, generating stations, condominiums, banks, hospitals, office structures, housing developments, homes, and all communication machines. Vehicles in faraway lands will include two reservoirs, so as to supply two cartridges on two batteries to restore battery life, PME voltage in each battery is maintained perpetually.