RU2428754C1 - Device to delete recorded information - Google Patents

Abstract

FIELD: information technologies.

SUBSTANCE: device to delete recorded information comprises the following: a DC source, a switching element, an AC to DC voltage converter, an external supply slot, a de-energising device, a flash sensor, an AC voltage device, a switch, a voltage divider, two devices of energy accumulation, a control device arranged as a microprocessor, a contactor, an indication device, a shaper - limiter, a four-wire cable and a joined four-contact connector.

EFFECT: improved reliability and quality of information deletion without the possibility of its recovery, reduced power consumption, reduced dimensions and weight of the device.

2 cl, 7 dwg

Description

The invention relates to computing instrumentation and can be used to erase records from heterogeneous semiconductor storage media, in particular non-volatile memory devices, flash memory, etc.

The basic principle of operation of semiconductor devices of volatile memory is to store the charge in an insulated gate. If a charge is stored in an insulated gate, then the threshold voltage U _{t of the} transistor can vary between two values, usually defined as “0” and “1”. The threshold voltage varies depending on the amount of charge stored in an insulated gate at a certain distance from it [1]. To erase recorded information in the form of residual conductivity, it is necessary to restore the initial value of the voltage of the potential barrier for charge carriers, the threshold voltage of which U _t is equal to the value of the erased state, i.e. the value preceding the entry. This means that a process must occur in which the charge Q _T stored at discrete centers or in an isolated (floating) shutter at a distance, for example L, from the shutter must at least take a value equal to “0”, and the fixed charge values at the interface, for example, a silicon insulator and a charge in a depleted silicon layer, take the initial value preceding the record.

State of the art

A device for erasing recorded information on heterogeneous semiconductor media [2], containing a darkened vacuum chamber, a device for generating steam, a compressor for changing vapor pressure, a 30 W incandescent lamp, an electromagnetic valve, a pump to ensure quick adsorbate inlet, a device for changing the distance of arrangement incandescent lamps, a device for measuring the conductivity of a film, a device for measuring the pressure of water vapor in the chamber, a device for measuring time and a power source, in Hur at an initial pressure of the residual atmosphere of 10 ^-3 ÷ 1 mm Hg the residual conductivity is excited by the light of a 30 W incandescent lamp located at a distance of 10 cm from the surface of the film — a semiconductor information carrier. Within 20 ÷ 60 seconds, measure the conductivity of the film. During the excitation time, the film conductivity reaches a stationary value of δ _sv ~ 10 ^-1 Ohm ^-1 cm ^-1 .

Adsorption is carried out by increasing the pressure using a compressor of water vapor coming from a steam generating device into a vacuum chamber with a vapor pressure of up to 10 ÷ 1000 mm Hg. for ~ 1 s, controlled by a special time measuring device. With an increase in the conductivity of the film, desorption is carried out by lowering the pressure to an initial level.

Quick inlet and outlet of the adsorbate is carried out using a pump and an electromagnetic valve. Erasing is carried out by an adsorbate pressure pulse, which is constantly monitored by a device for measuring the pulse pressure generated in a darkened vacuum chamber.

The disadvantage of this device is the complexity of the design, the use of expensive equipment, high energy consumption, it takes a lot of time to prepare the erasure process, special monitoring equipment is needed to control the parameters of the components of the device, limited application.

A device known as USB 2.0 in a computer, which is described in technology [3], a device for erasing records from heterogeneous semiconductor storage media with non-volatile memory, flash memory (devices having a special USB connector for connecting to a computer), comprising: a monitor, keyboard, mouse, system unit that includes a host (Host), hubs (Hub) and four-pin connectors (connectors) for connecting flash memory to a computer, two for transmitting a signal and two for supplying voltage pi power, cable and power supply. Data erasure transmission is initiated by the host. Transactions on the USB bus consist of two or three acts: sending a marker packet, a data packet, a transaction status packet.

The disadvantage of this device is that the information that needs to be erased may remain in the computer’s RAM, functional devices themselves cannot directly transmit information about erasing, since USB is an output bus from the computer’s system unit, for which it is necessary to have an operating system, which would support USB (Windows 98 Second Edition) and perform software functions. In addition, the high energy costs associated with the need to provide power to a number of PC components, a relatively long erasure time, which is determined by the time the computer takes to work and the transfer of the necessary commands to erase information, the possibility of restoring information, since there is always the possibility that the recorded information will remain in the computer's RAM.

The closest is a device for erasing recorded information [4] from heterogeneous semiconductor data carriers containing a direct current source, a power switch, a current divider, a damping device, an energy storage device on capacitors, a switching device, a field-forming system made on solenoids, a four-wire control device cable and four-pin connector. The field-forming system has a frame on which four solenoids are installed one inside the other,

The windings of the coils of a pair of solenoids are made oblique with the slope of the turns of the wires of the windings in the planes of the narrow walls of the frame to its longitudinal edges of the solenoids at an acute angle. The winding of the wires of the coils of the second pair of the solenoid is made zigzag, inclined in the plane of the wide and narrow walls of the frame at acute angles. Under the action of the rapidly changing electromagnetic field created by the device, the structure of charge placement on the semiconductor information carrier changes.

The disadvantage of this device is that to destroy information it is necessary to apply an external magnetic field to semiconductor thin-film non-volatile memory systems, the complexity of the process and design of the field-forming system to create a pulsed magnetic field, high energy costs associated with the need to power a number of capacitors of the energy storage device, large dimensions and the mass of the device.

The claimed invention solves the problem of improving the quality of erasing information without the possibility of its recovery due to exposure to an electric field and high voltage to change the width of a potential barrier (DE) [5] in the space charge region of a semiconductor element of a thin-film non-volatile memory system. For this, conditions are created for the tunneling transition of electrons from one region to another due to the proportionality of the filling density of energy levels from the side of the barrier, as well as the density of free energy levels from the opposite side of the barrier. Electrons cross the barrier in both directions. Conditions are created when the width of this barrier becomes comparable with the electron wavelength. An electron passes through the barrier without energy loss and provides the substitution process through charge transfer through the potential barrier, changing the semiconductor structure throughout the recording field and filling all the energy levels of electrons, which are directed by special algorithms to the electron flows crossing the potential barrier and placed at energy levels. Thus, they replace the previously stored at the previous record, the stored charges in isolated gates by the newly introduced ones according to a special algorithm with code writing, changing the structure of the memory record. Exposed increased electrical voltage leads to burnout of the controller and elements of the thin-film electric system of non-volatile memory.

This process provides the opportunity to reduce power consumption, simplify the design and manufacturing technology of the device by reducing the energy of the drives.

The technical result of the invention is to increase the reliability and quality of erasing information while reducing energy costs, overall dimensions and mass of the device.

Description of figures and symbols

Figure 1 presents a block diagram of a device for erasing recorded information.

Figure 2 shows a block diagram of an alternating voltage device.

Figure 3 shows a timing diagram characterizing the shape of the electrical signals of high voltage.

Figure 4 shows the electrical circuit of the first and second energy storage device.

Figure 5 presents a circuit diagram of a first electronic key.

Figure 6 presents a circuit diagram of a current generator.

Figure 7 presents a circuit diagram of a second and third electronic key.

The following notation is introduced in the figures:

1 - battery (A1);

2 - switching element (EC2);

3 - voltage converter (PNZ);

4 - external power connector (RVP4);

5 - power switch (VP5);

6 - voltage divider (DN6);

7 - an alternating voltage device (UPN7);

8, 9 - energy storage devices (UNE8, UNE9);

10 - switch (VK 10);

11 - microprocessor (MP 11);

12 - microcontroller (MK12);

13 - bus controller (KSh13);

14 - indication device (UI14);

15 - contactor (K15);

16 - flash sensor (DF16);

17 - shaper-limiter (F17);

18 - four-wire cable (ChK18);

19 - four-pin connector (ChS19);

20 - flash memory (FP20);

21 - the first electronic key (KE1);

22 - current generator of rectangular pulses (G);

23 - delay line (LZ);

24 and 25 - the second and third keys are electronic (102) and (KEZ).

The numbers in the figures, written in small print, indicate the numbers of inputs and outputs of the blocks. In the text of the description of the invention, these numbers are enclosed in parentheses.

The list of blocks of the claimed device and their functional purpose

The technical result of the invention is achieved due to the fact that the device for erasing recorded information contains (Fig. 1): battery A1, switching element EK2, voltage converter PNZ, external power connector RVP4, power switch VP5, voltage divider DN6, variable voltage device UPN7, first UNE8 and the second UNE9 energy storage device, VK10 switch, MP11 microprocessor, MK12 microcontroller, KSh13 bus controller, UI14 indicating device, K15 contactor, DF16 flash sensor, F17 shaper-limiter, four hprovodnoy CHK18 cable, uses a four-connector CHS19, flash memory FP20. UPN7 includes: the first key is electronic KE1 21, the current generator of rectangular pulses G 22, the delay line LZ 23, the second KE2 24 and the third KEZ 25 electronic keys.

Battery 1 provides power to the recording erase device during transportation and has a “plus” input – output (1) power terminal and a common zero terminal (2). As a battery, a battery of 7 ± 0.5 V with a capacity of at least 0.7 Ah can be used. In stationary conditions in the battery charging mode 1 terminal (1) “plus” performs the function of a power input. When the device is operating on battery 1 terminal (1) “plus” performs the function of power output.

Switching element 2 is designed to switch battery 1 from charging mode in stationary conditions using a voltage converter 3 and an industrial network of 220 V, 50 Hz to a stand-alone - normal mode of operation of the device from battery 1, which is designed to be supplied with a constant voltage of 7 ± 0.5 V electrical units and components of the device during its transportation. EC2 contains (Fig. 1) a first common zero terminal (4), a plus second terminal (2), a third power output terminal (3), and a fourth power input terminal (1). EK2 and has a normally open (NO) contact between the second and fourth terminals and a normally closed (NC) contact between the second (2) and third (3) terminals and a diode. The diode is connected to the fourth terminal (1) by one output, and the second terminal (2) by the other. EK2 works on the principle of a relay, when a voltage of 7 ± 0.5 V is applied to its terminal (1), the NO contact closes. Battery 1 is charged through a diode, and power to the device and units is supplied from voltage converter 3. If there is no voltage on terminal (1), the NC contact is closed, and battery 1 is charged. A voltage of 7 ± 0.5 V is supplied to the blocks from battery 1 from terminal (3) EC2.

The PNZ voltage converter is intended for converting an alternating voltage of an industrial network 220 V, 50 Hz into a plus DC voltage of 7 ± 0.5 V. The PNZ has an input (1) and an output (2) of power supply and a common zero terminal (3).

The external power connector 4 is designed to connect the device to an industrial network and has (1) a power input and an output (2) of power with two contacts for a two-wire cable and a common zero terminal (3).

The power switch 5 is designed to supply power to the blocks of the device for erasing recorded information for connecting flash memory 29 to a four-pin connector (connector) 19 and has a first input (1) of power, a second input (3) of signal and output (2) of power.

The voltage divider 6 has a power input (1) and first (2) and second (3) power outputs.

The AC voltage device 7 is designed to create a pulsed high-voltage voltage of 400 ± 50 V and has an input (1) of a direct current supply voltage, an output (2) of a pulsed power supply of 400 ± 50 V and a common zero terminal (3), UPN7 contains (figure 2 ): the first key is electronic 21 KE1, the current generator of rectangular pulses 22 G, the delay line 23 LZ, the second 24 and third 25 keys are electronic KE2 and KEZ. KE1 21 (Fig.2, 5) has a power input (1) and a signal output (2) and one common zero terminal (3). The rectangular pulse current generator 22 (Fig. 2,6) has a signal input (1), a power input (4), a rectangular pulse signal output (2) and one common zero terminal (3). The delay line 23 (figure 2) has an input (1) and an output (2) signal. The second and third electronic keys 24 and 25 (FIGS. 2, 7) have a first input (1) signal, a second power input (4), pulse power output (2) and a common zero terminal (3).

The input (1) of the power of the first key of the electronic 21 is connected to the input (4) of the power of the generator 22 and to the inputs (4) of the power of the second 24 and third 25 electronic keys (Fig.2). The terminals (3) of the common zero of the first electronic key 21, the generator 22, the second 24 and the third 25 electronic keys are connected.

The output (2) of the signal of the first key of the electronic 21 is connected to the input (1) of the signal of the current generator 22, and its output (2) of the signal is connected to the inputs (1) of the signal delay line 23 and the second key of the electronic 24. Output (2) signal of the delay line 23 is connected to the input (1) of the signal of the third electronic key 25. The outputs (2) of the pulse power of the second 24 and third 25 electronic keys are connected and are the output (2) of the pulse power of the AC voltage device 7.

The energy storage devices UNE8 and U1-1E9 (Fig. 1.4) are designed to create a pulse voltage with an amplitude of 350-400 V and have an input (1) of a pulse power voltage of 400 ± 50 V (Fig. 3), an output (2) of pulse power and terminal (3) total zero and are made in the form of capacitive storage capacitors.

The switch 10 is designed to signal the start of the device for erasing recorded information according to a specially established algorithm of the microprocessor 11 and has a signal output (1).

The microprocessor 11 is designed to control the device for erasing recorded information in automatic mode and has three inputs, five outputs and one common zero terminal. The first input (1) of the switch signal, the second (2) power supply and the third (3) signal DF16. Signal outputs: the first (4) control of the contactor 15, the second and third (5) and (6) control of the display device 14, the fourth and fifth (7) and (8) control shaper-limiter 17.

The microprocessor 11 contains (Fig. 1) a microcontroller 12, a bus controller 13, three inputs and five outputs. The first (1), second (2) and third (3) inputs and the first (4), second (5), third (6), fourth (7) and fifth (8) outputs.

The microcontroller 12 is designed to control the device for erasing, generating and generating pulses with a repeating code in accordance with the established program, with a certain algorithm and the number of cycles to ensure the substitution process, filling all energy levels with generated pulses throughout the recording field, in accordance with the program, thereby That provides a change in the structure of the data of the memory chip and the formation of control voltages for the contactor 15 and the indicating device 14.

The microcontroller 12 has three inputs: the first (1) power input, the second input (5) of the DF16 flash sensor signal, the third input (2) of the VK10 switch signal and four outputs: the first (5) and second (6) control of the UI14 indicating device, third (7) control the bus controller KSh 13 and the fourth (6) control contactor K15.

The bus controller 13 has a signal input (1), the first (2) and second (3) signal outputs.

The inputs of the first (1), second (2) and third (3) microprocessors MP11 are respectively the inputs of the first (2), second (1) and third (5) of the microcontroller 12. The outputs of the first (4), second (5) and third ( 6) microprocessor 11 are respectively the outputs of the first (6), second (3) and third (4) microcontroller 12. The outputs of the fourth (7) and fifth (8) microprocessor MP11 are the outputs of the first (2) and second (3) KS bus controller 13.

The fourth output (7) of the MK12 microcontroller is connected to the input (1) of the KSh13 bus controller, and its outputs are the first (2) and second (3), which are the fourth (7) and fifth (8) outputs of the MP11 microprocessor, respectively connected to the first ( 1) and second (2) inputs of the shaper Ф17.

Indication device 14 is designed to indicate the power supply to the device units and the operability of the device in the mode of erasing recorded information and has a first input (1) signal, a second power input (2) and a common zero terminal (3). In the display device 14 there are two indicators "Power" and "Flash". The “Power” indicator lights up to indicate that the erase device is powered by battery 1 or an external network. The “Flash” indicator glow informs about the detection of a semiconductor storage medium and the correct connection of flash memory 20 to the four-pin connector 19.

Contactor 15 is designed for short-term (pulse) switching of high voltage and has three inputs and two outputs. The first (1) and second (2) pulsed power inputs, the third (5) input signal and the first (3) and second (4) pulsed power outputs.

Flash sensor 16 is designed to generate an information signal that a non-uniform semiconductor storage medium flash memory 20 (Fig. 1) is detected in the device for erasing recorded information and has a power input (1) and a signal output (2) and an input-output light beam (dotted line in figure 1). The flash sensor 16 is made with a slot for accommodating flash memory, through which, in the absence of flash memory, a light beam (dotted line in Fig. 1) passes through the DF16 photocell. If there is a flash in the flash memory slot, the beam breaks and the flash 16 sensor fires, creating a signal at the output of DF16. This signal through VK10 provides power to all units of the device and the inclusion of MP11.

Shaper-limiter 17 is designed to generate signals of a certain polarity and to prevent the output of the outputs (7) and (8) of the microprocessor 11 of an increased electrical voltage of 33 V and has first (1) and second (2) signal inputs, the first (3) and second ( 4) signal outputs.

The four-wire cable 18 has four wires: the first (1), second (2) and third (3) signal, fourth wire (4) to connect to the common zero terminal.

The four-pin connector (connector) 19 is designed to connect a semiconductor storage medium and has four terminals: the first (1), second (2), third (3) and fourth (4). The output of the connector is designed to connect with the corresponding terminals of the flash memory 20.

Electrical connections of the claimed device

The battery 1 is connected by an input-output (1) of power to the output-output (2) of the power of switching element 2, which is connected with its input (1) to the output (2) of the voltage converter 3, the input (1) of which is connected to the output (2) ) power supply of the external power connector 4, through which the voltage of the industrial network 220 V, 50 Hz is supplied. The output (3) of the power of switching element 2 is connected to the input (1) of the power of the power switch 5 and to the input (1) of the power supply of the flash sensor 16, and the output (2) of the signal sensor of the flash 16 is connected to the input (3) of the signal microprocessor 11 and the input ( 3) control power switch 5.

The output (2) of the power switch 5 is connected to the input (1) of the voltage divider 6 and the input (1) of the power supply of the AC voltage device 7, the output of which is connected to the outputs (1) of the pulse power supply of energy storage devices 8 and 9, and their outputs (2 ) the power supply is connected to different inputs (1) and (2) of the power supply of the contactor 15. The voltage divider 6 is connected by the first output (2) of the power supply to the input (2) of the microprocessor 11. The microprocessor 11 is connected to the signal output (1) to the signal output (1) switch 10, outputs (5) and (6) signal to inputs (1) and (2) signal indicating devices 14, output (4) signal to the input (5) of the signal contactor 15, and outputs (7) and (8) signal to the inputs (1) and (3) of the shaper-limiter 17. Outputs (2) and (4) the signal shaper-limiter 17 is connected to the inputs (2) and (3) signal through the contacts (2) and (3) of the four-wire cable 18 to the contacts (2) and (3) the signal and four-pin connector (connector) 19 to the contacts (2) and (3) flash signal memory 20.

The voltage divider 6 by the second output (3) of the power supply is connected to the contact (1) of the four-wire cable 18, and the contacts (2) and (3) of the four-wire cable 18 are connected to the outputs (3) and (4) of the signal contactor 15 and the outputs (2) and (4) shaper-limiter 17.

The common zero terminals of all units of the device and the four-wire cable are connected together.

The operation of the device for erasing recorded information

The erase device is powered during transportation from battery 1, and under stationary conditions from an industrial network of 220 V, 50 Hz with recharging of battery 1 with a constant voltage of 7 ± 0.5 V. Flash memory 20 is connected to a four-pin connector 19. Flash sensor 16 detects a connected to the connector 19, a non-uniform storage medium flash memory 20 and upon receipt of power at its power input (1), flash sensor 16 generates an information signal at its output (2) signal. The power to the flash sensor 16 and to the power switch 5 when operating in stationary conditions is supplied from an industrial network of 220 V, 50 Hz, which is supplied through an external power connector 4 to the input (1) of the voltage converter 3, where the voltage stabilizes to a certain value in the range values 7 ± 0.5 V, for example 7 V. A stabilized supply voltage is supplied from the output (2) of the voltage converter 3 to the input (1) of the power supply of switching element 2, which is designed to automatically switch the power between the converter 3 and battery 1. At the input (1) of the power supply of the 7 V switching element, it closes the contacts between the input (1) of the power supply and the output (3) of the power supply. The battery 1 is recharged during this switching through a diode circuit connecting the power input (1) and the output-input (2) of the switching element (2).

Battery 1 charging time does not exceed 1 hour. When working from battery 1, the power supply voltage of the industrial network 220 V, 50 Hz is disconnected from the external power connector 4. As a result of this operation, power is not supplied to the power input of voltage converter 3, and, accordingly, voltage converter 3 is supplied from output (2) it is not supplied to the input (1) of the power of switching element 2. The switching element 2, by the principle of the relay, switches automatically, connecting the contacts of the output-input (2) power of the switching element 2 and the output (3) of the power supply. On the diode circuit of the switching element 2 to recharge the battery 1, power is not supplied (figure 1). The inputs (1) of the power supply of the flash 16 sensor and switch 5 are supplied with plus 7 V voltage from the battery 1 through a normally closed contact from the output-input (2) of switching element 2. Power is supplied through this circuit through the power switch 5 to all blocks and nodes electrical block diagram (figure 1) in the presence of power on all blocks and in the presence of a signal at the output of VK10.

The erase device is in the storage mode and waiting for erasing information.

In this mode, the eraser transfers the signal generated at the output (2) of the flash 16 signal sensor, upon detection of a connected flash memory 20, which goes to the input (3) of the signal power switch 5 and closes its normally open contact.

A stabilized supply voltage of 7 V is supplied (Fig. 3a) to the input (1) of the power supply of the voltage divider 6 and to the input (1) of the power supply of the AC voltage device 7 (Fig. 1), and accordingly, it is also supplied to the input (1) of the power supply of the first electronic key 21 (figure 2, 5) and to the inputs (4) of the power supply of the current generator of rectangular pulses 22, the second and third keys of electronic 24 and 25.

When the power switch 5 (Fig. 1) is turned on, the first electronic key 21 (Fig. 5) generates a control signal in the form of a rectangular pulse (Fig. 3b) at its signal output (2), which is fed to the input (1) of a rectangular rectangular current generator pulses 22 (Fig.6) and starts it. The current generator 22 (Fig.6) generates a square wave signal, for example in the form of a "meander" (Fig.3B). This signal is fed to the signal input (1) of the second key of the electronic 24 (Fig. 7) and to the signal input (1) of the delay line 23. At the output (2) of the signal delay line 23, a rectangular signal is generated, shifted by half the T / 2 period "Meander" of the signal of the current generator 22 (Fig 3d). The signal from the output (2) of the current generator 22 (Fig.3c) is fed to the input (1) of the signal of the second key of the electronic 24, which at its output (2) signal forms a square wave signal (Fig.3d). Upon receipt of signals at the inputs (1) of the signal keys of electronic 24 and 25, the current from the output (2) of the power switch 5 through the input (1) of the power supply of the AC voltage 7 is supplied to the input (4) of the power of electronic keys 24 and 25 (Fig. 7 ) and through the inductor L1 of the key electronic 24 (Fig.7) and the open transistor VT3 goes to the terminal (3) of common zero. When applying a low voltage of less than 0.7 V, the TTL logic Zero level to the inputs (1) of the electronic keys 24 and 25, the transistor VT3 closes, and the current in the coil L1 cannot instantly decrease due to its circuit time constant. As a result, a positive pulse in the form of a voltage surge appears at the drain of the transistor VT3. At the output (2) of the key of the electronic 24, a signal (Fig. 3d) of a positive polarity is generated, and at the output (2) of the key of the electronic 25 a signal (Fig. 3f) of a positive polarity with a delay of T / 2 is formed for half the oscillation period of the signal of the generator 22. signals through the diode VD1 (Fig.7) from the outputs (2) of the keys of electronic 24 and 25 (Fig.3d, e) and the output (2) of the signal switching power supply of the AC voltage device 7 are fed to the input (1) of the switching power supply of energy storage devices 8 and 9 and charge them (Fig. 4) to a level of 400 V ± 5% (Fig. 3g). Upon reaching the required voltage level, for example, after 1-2 seconds, it is supplied to the inputs (1) and (2) of the power supply of the switch 15 (Fig. 1). Simultaneously with the outputs (2) and (3), the power of the voltage divider 6 is supplied to the power input (2) of the microprocessor 11 and to the power input (1) via a four-wire cable 18, then to the power input (1) of the four-pin connector 19 and, respectively, to the input (1) the power supply of the flash memory 20, and from the outputs (5) and (6) of the signal microprocessor 11, the inputs (1) and (2) of the indication device 14 receive a supply voltage and signals that the erase device is in storage mode and erasing information. At the same time, on the display device 14, the “Power” and “Flash” indicators light. The “Power” indicator informs that the erase device is powered by battery 1 or an external network. The Flash indicator informs about the detection of a semiconductor storage medium and the correct connection of the flash memory 20 to the four-pin connector 19.

After receipt of the output (2) of the microprocessor 11 power to the input (1) of the power of the microcontroller 12 and the signal generated in the flash sensor 16 to the input (3) of the signal microprocessor 11 and the input (5) of the signal microcontroller 12 (Fig.3k). These signals provide, in accordance with the established program, the generation of signals with a repeating code generated in the microcontroller 12. At the output (7) of the signal microcontroller 12, pulses are generated with a certain algorithm and the number of cycles. In the emergency erase mode, the switch 10 is put into active mode. From the output (1) of the signal switch 10 to the input (1) of the microprocessor 11 and the input (2) of the microcontroller 12 receives a control signal in accordance with the program for generating pulses. From the output (7) of the signal microcontroller 12 through the bus controller 13 of the outputs (2) and (3), which are the write code for the flash memory 20, and the outputs (7) and (8) of the microprocessor 11 through the shaper-limiter 17 (Fig. 1 ) on a four-wire cable 18 through a four-pin connector 19, the signals are fed to the contacts (2) and (3) of the flash memory 20.

At the end of the generation of signals with a repeating code, the microprocessor 11 generates a control voltage at the output (6) of the signal (Fig.3z) to close the normally open (BUT) contacts of the contactor 15. For each of the output circuits of the contactor 15 connected to the contacts (2) and ( 3) a four-wire cable 18, after the normally open (BUT) contacts of the contactor 15 are closed, an impulse current flows (Fig. 3i).

A pulsed current of 2.0 A generated by discharging the accumulated voltage up to 400 V on energy storage devices 8 and 9 is supplied to the inputs (2) and (3) of flash memory 20, thereby burning out the controller and the elements of the electrical wiring of the thin-film system non-volatile memory.

After the destruction of information on the display device 14, the Flash indicator does not light. The contacts of the power switch 5 open, the power to the nodes and blocks of the device erase recording is not supplied.

Features of the invention

A switching element that contains the first common zero terminal, the second plus terminal, the third power output terminal, the fourth power input terminal and has a normally open (NO) contact between the second and fourth terminals and a normally closed (NC) contact between the second and third terminals and a diode, which is connected to the fourth terminal with one terminal and the second terminal, an AC / DC converter, which has a power input and output and a common zero terminal, an external power connector, which has a power input and output and a common zero terminal, an alternating voltage device that has a DC input of a supply voltage, a low voltage pulse output and a common zero terminal, a second energy storage device, a switch that has a signal output, a contactor that has first and second pulse power inputs and a third input signal and first and second outputs of pulse power, a flash sensor, which has a power input and a control signal output and a slot through which, in the absence of flash memory, the light beam of the flash sensor passes, the limiter-limiter, which has the first and second signal inputs and the first and second outputs are signal, and the control device is made in the form of a microprocessor, which has a common zero terminal, the first switch signal input, the second flash sensor signal input and the third power input, the first control output contactor, the second and third outputs of the control of the display device, the fourth and fifth outputs of the control shaper-limiter, in addition, the display device has a first signal input, a second power input and common ground terminal.

The DC source is made in the form of a battery, has a plus terminal and a power input-output terminal and a common zero terminal, and the power-off device has a first power input and a second signal input and power output.

The voltage divider has a power input and first and second power outputs.

Energy storage devices have a pulse power input, a power output, and a common zero terminal.

The microprocessor is connected by the first signal input to the signal output of the signal switch, the first and second signal outputs are connected to the corresponding signal to the inputs of the indicating device, the third signal output is connected to the input of the signal contactor, and the fourth and fifth signal outputs are connected to the signal inputs of the driver-limiter.

The battery is connected by an input-output power to the output-output of the power of the switching element, which is connected by its power input to the output of the voltage converter, the power input of which is connected to the power output of the external power connector.

The power output of the switching element is connected to the power input of the power switch and to the power input of the flash sensor, the signal output of which is connected to the signal input of the microprocessor and the power switch control input, the power output of which is connected to the input of the voltage divider, the input of the switch and the power input of the AC voltage output which is connected to the pulse power inputs of energy storage devices, and their power outputs are connected to different power inputs of the contactor.

The voltage divider by the first power output is connected to the microprocessor power input.

The outputs and signal of the shaper-limiter are connected to the signal inputs through two contacts of the four-wire cable to two signal contacts and a four-pin connector (connector) to the signal flash memory contacts.

The voltage divider by the second power output is connected to one contact of the four-wire cable, and the other two contacts of the four-wire cable are connected to the outputs of the signal contactor, and the common zero terminals of all units of the device and the four-wire cable are connected together.

The AC voltage device contains: the first electronic key, which has a power input, a signal output and one common zero terminal, in addition, the second and third electronic keys have one signal input, one power input, one pulse power output and a common zero terminal , the square-wave current generator has a first signal input, a second power input, a rectangular pulse signal output and a common zero terminal, a delay line that has a signal input and output. The power input of the first electronic key is connected to the power input of the generator and to the power inputs of the second and third electronic keys, the common zero terminal of the first electronic key, generator, second and third electronic keys are connected. The signal output of the first electronic key is connected to the signal input of the current generator, and its signal output is connected to the inputs of the signal delay line and the second electronic key, the signal output of the delay line is connected to the signal input of the third electronic key. The pulse power outputs of the second and third electronic keys are connected and are the pulse power output of the AC voltage device.

An example of a device for erasing recorded information

The device for erasing recorded information is made in accordance with the block diagram of FIG. 1, the AC voltage device 7 is made in accordance with the block diagram of FIG. 2 and circuit diagrams of FIGS. 5, 6, 7. Energy storage devices 8 and 9 are made in accordance with the circuit diagram of FIG. .four.

As a power source used battery 1 TP1,2. The switching element 2 is based on the transistor BVZ11. As a voltage converter 3, a step-down transformer, a rectifier and a stabilizer are used.

The external power connector 4 is made in the form of standard sockets with a common zero terminal for the euro connector.

The power switch 5 is made on a VTB24-600 V simistor.

The voltage divider 6 is made on a resistor type C2-33.

In the alternating voltage device 7, the first electronic key 21 is made on a KT315 transistor, the rectangular pulse generator 22 is made on a KR1006 VI1 microcircuit, the delay line 23 is made on a KR1006 VI1 microcircuit, the second and third electronic keys 24 and 25 are made on VT1-BC846, VT2- circuits BC856, VT3-iRFL014N, VD1-D220A.

Energy storage devices 8 and 9 are made on capacitors K50-77.

The switch 10 is made in the form of a switch type TV 1-2.

The microprocessor 11 is made on the AT91SAM7S256 chip.

The microcontroller 12 is made on a chip type KR5811IK1.

The bus controller 13 is made on a chip type PD1USBD12 /

Indication device 14 is made on LEDs type AL307K.

The contactor 15 is made on 2 chips KR293KP11AP.

Flash sensor 16 is made on elements of type BPX43-3.

Shaper-limiter 17 is made on diodes type D 132-80-14.

The four-wire cable loop 18 is a shielded pair (loop).

As a four-pin connector 19, an “A” type connector is used, which is used to connect a PC.

The proposed design of the device for erasing recorded information provides reliable erasure of information from heterogeneous semiconductor information carriers without the possibility of its recovery due to exposure to an electric field. During substitution, an electric field is applied, as the main element of the flash media are TIR-based field structures.

In this case, the conditions for the tunneling transition of electrons from one region to another are created, for which the width of the potential barrier changes, which becomes comparable to the electron wavelength at which the electrons pass through the barrier without energy loss and provide a substitution process using special algorithms that regulate the transition of electrons through potential barrier. Algorithms change the semiconductor structure throughout the recording field, filling all energy levels, and thus replace previously placed and stored charges in isolated gates with newly introduced ones with code writing and subsequent exposure to increased electric voltage, which ensures the burnout of the controller and the elements of the electrical wiring of the thin-film non-volatile system memory.

The invention solved the problem of improving the reliability and quality of erasing information without the possibility of its recovery, reducing energy consumption by using less energy-intensive devices of pulsed small-sized converters for compact energy storage devices and simplifying it by eliminating a complex process and design of a field-forming system, damping device, switching device, and reduced dimensions and weight of the device.

Information sources

1. Nonvolatile Semiconductor Memory Technology. Edited by William D. Brown, Joe E. Brewer.

2. Inventions "Method of erasing recorded information", ed. St. No. 777680, MKI G11B 3/66, published 1980

3. A.Kalyga. USB 2.0 Technology, www.3dnews / storage / 169V, December 22, 2003

4. The invention of "Device for erasing recorded information", US Pat. No. 2346345, MKI G11C 16/14, published 2009

5. I.E. Efremov, I.Ya. Kozyr, Yu.I. Gorbunov, Microelectronics. - M.: Higher School, 1986, pp. 87-94.

Claims (2)

1. A device for erasing recorded information, comprising: a direct current source, a switch, a voltage divider, an energy storage device, a control device, a four-wire cable that has first, second, and third signal wires and a fourth wire connected to a common zero terminal, and a four-pin connector , which has the first, second, third and fourth terminals and four outputs, characterized in that they are introduced: a switching element that contains the first common zero terminal, the second plus terminal, the third terminal at the power output, the fourth terminal of the power input and has a normally open contact between the second and fourth terminals and a normally closed contact between the second and third terminals and a diode, which is connected to the fourth terminal by one output and the second terminal by the other, a voltage converter that has power input and output and a common zero terminal, an external power connector that has a power input and output and a common zero terminal, an alternating voltage device that has a DC voltage input, a pulse output low-voltage voltage and a common zero terminal, a second energy storage device, a contactor that has first and second pulse power inputs and a third signal and first and second pulse power outputs, a flash sensor that has a power input and a control signal output and a slot through which in the absence of flash memory passes the light beam of the flash sensor, shaper-limiter, which has the first and second signal inputs and the first and second outputs are signal, and the control device is made in the form of a microprocessor, which has a common zero terminal, the first input of the switch signal, the second input of the flash sensor signal and the third power input, the first output of the contactor control, the second and third outputs of the control of the display device, the fourth and fifth outputs of the control of the shaper-limiter, in addition, the display device has the first a signal input, a second power input and a common zero terminal, in addition, the DC source is made in the form of a battery and has a plus input and output terminal and a common zero terminal, a power switch that the first one has a first power input and a second signal input and power output, in addition, the voltage divider has a power input and first and second power outputs, energy storage devices have a pulse power input, a power output and a common zero terminal, and the microprocessor is connected to the first signal input with the output of the signal switch, with the corresponding signal to the inputs of the display device, the third signal output is connected to the input of the signal contactor, and the fourth and fifth signal outputs are connected to the signal the inputs of the shaper-limiter, in addition, the battery input-output power is connected to the output-output of the power of the switching element, which is connected by its power input to the output of the voltage converter, the power input of which is connected to the output of the external power connector, and the output of the switching element is connected to the power switch power input and the flash sensor power input, the signal output of which is connected to the signal input of the microprocessor and the power switch control input, the power output which is connected to the input of the voltage divider, the input of the switch and the power input of the AC voltage device, the output of which is connected to the pulse power inputs of the energy storage devices, and their power outputs are connected to different power inputs of the contactor, in addition, the voltage divider is connected to the input by the first power output microprocessor power supply, and the signal outputs of the shaper-limiter are connected to the signal inputs through the second and third contacts of the four-wire cable with two contacts signal and through a four-pin connector with flash memory signal contacts, in addition, the voltage divider is connected to the first pin of the four-wire cable with a second power output, and the second and third pins of the four-wire cable are connected to the outputs of the signal contactor, and the fourth terminals of the four-wire cable, four-pin connector and flash -Memory attached to a common zero. 2. The device for erasing recorded information according to claim 1, characterized in that the alternating voltage device contains: a first electronic key that has a power input, a signal output and one common zero terminal, in addition, the second and third electronic keys have one signal input , one power input, one pulse power output and a common zero terminal, the square-wave current generator has a first signal input, a second power input, a square-wave signal output and a common zero terminal, a delay line LCD, which has a signal input and output, in addition, the power input of the first electronic key is connected to the power input of the generator and to the power inputs of the second and third electronic keys, the common zero terminal of the first electronic key, generator, second and third electronic keys are connected, and the output the signal of the first electronic key is connected to the signal input of the current generator, and its signal output is connected to the inputs of the signal delay line and the second electronic key, the signal output of the delay line is connected inen to the signal input of the third electronic key, in addition, the pulse power outputs of the second and third electronic keys are connected and are the pulse power output of the alternating voltage device.

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