RU207354U1 - INSTALLATION FOR MEASURING THE ION BEAM COMPOSITION - Google Patents

Abstract

The utility model relates to the field of installations for determining the presence, intensity, density or energy of radiation or particles. The technical result of the utility model is to increase the accuracy of measurements of the energy characteristics of the ion flux and is achieved due to the fact that the installation for measuring the composition of the ion beam, containing the detector is located across the ion beam at the output shaft of the stepper motor. The detector is made in the form of four pad elements made of silicon, the detector is controlled by a stepper motor controller, on the sides of the detector in the detector unit along the movement axis, limit switches are mounted with the ability to limit the linear movement of the detector, and the preliminary, operational and output amplifiers are connected in series to the analog output of the detector. 2 c.p. f-ly, 1 dwg.

Description

The utility model relates to the field of installations for determining the presence, intensity, density or energy of radiation or particles [G01T 1/20].

From the prior art known DEVICE FOR MONITORING THE PARAMETERS OF ION BEAM [RU 2520940 C2, publ. 06/27/2014], containing a scintillator installed perpendicular to the direction of the ion beam, photodetectors located evenly around the perimeter of the scintillator, a scheme for recording and processing signals from photodetectors, characterized in that the scintillator is made in the form of a disk-shaped opaque chamber, and the photodetectors are installed in the holes made in its side wall, and equipped with light filters transparent to infrared radiation, while the scintillator, together with the photodetectors, is enclosed in a sealed envelope with openings for the inlet and outlet of the scintillating gas. The closest in technical essence is the ELECTRONIC-OPTICAL POSITIONAL-SENSITIVE DETECTOR [Scientific Instrumentation, 2000, volume 10, No. 1], containing a circuit with sequential signal conversion, which includes an assembly of two microchannel plates, a fluorescent screen, a lens and a multi-element photodetector, connected to an analog-to-digital converter. The signals are stored in the memory of a spectrum accumulator controlled by a computer. The main technical problem of the analogue and prototype is the high measurement error due to the low signal-to-noise ratio and the inability to adjust the position of the detector relative to the measured particle flux.

The task of the utility model is to eliminate the shortcomings of the prototype.

The technical result of the utility model is to improve the accuracy of measurements of the energy characteristics of the ion flow.

The specified technical result is achieved due to the fact that the claimed installation for measuring the composition of the ion beam containing, detector, analog-to-digital converter, memory module, characterized in that the detector is mounted in the detector module across the ion beam on the output shaft of the stepper motor, analog output from the detector is connected simultaneously to the ADC through a series-connected preliminary, operational and output amplifiers and to the comparators of the control and measurement unit, while the output amplifiers are connected to the ADC through a delay cable, the comparators are connected to a trigger switch, the outputs of which are through a coincidence circuit, a delay line, a BUSY circuit "And the driver are connected to the programmable logic integrated circuit, to the other input of which the ADC is connected, while the information outputs of the" BUSY "circuit, the driver and the programmable logic integrated circuit are connected to the ADC through the control circuit, and the programmable logic integrated circuit is made with the possibility of connecting via a USB interface with a control computer, and the power supply of the detector unit and the control and measurement unit is made from separate power supplies.

In particular, the detector unit is made in the form of a rigid structure and is connected to the control and measurement unit by a cable communication line for data transmission.

In particular, the detector is in the form of a silicon detector.

In particular, the detector is made in the form of four pad sensitive elements.

In particular, the linear stepper motor is controlled by the stepper motor controller.

In particular, on the sides of the detector along the axis of movement, limit switches are mounted with the possibility of limiting the linear movement of the detector.

In particular, the limit switches are included in the control circuit of the stepper motor controller.

In particular, the preamplifier is two-channel.

In particular, two output amplifiers are connected to each operational amplifier.

In particular, the trigger switch is controlled from the controller of the control and measurement unit.

In particular, the power supply of the control and measurement unit is made separate for the analog and digital parts.

The utility model is illustrated by a drawing.

The drawing shows a block diagram of a complex of devices for measuring the composition of the ion beam.

The drawing indicates: 1 - detector unit, 2 - control and measurement unit, 3 - line stepper motor, 4 - output shaft, 5 - silicon detector with sensitive elements, 6 - stepper motor controller, 7 - limit switches, 8 - preamplifier , 9, 10 - operational amplifiers, 11-14 - output amplifiers, 15, 16 - comparators, 17 - trigger switch, 18 - ADC, 19 - coincidence circuit, 20 - delay line, 21 - "BUSY" circuit, 22 - shaper , 23 - controller, 24 - programmable logic integrated circuit, 25 - control circuit, 26 - USB module, 27 - personal computer, 28 - power supply unit of the detector module, 29 - power supply unit of the control and measurement unit.

Implementation of the utility model

The device for measuring the composition of the ion beam (see Fig.) Contains a detector unit 1 and a control and measurement unit 2 connected to unit 1. The detector unit 1 is enclosed in a metal case with an inlet and outlet window for the passage of particles. Inside the detector module 1, a linear stepper motor 3 is mounted, on the output shaft 4 of which a silicon detector 5 is mounted, consisting of four pad detectors (not shown in the drawing). The stepper motor 3 is connected to the control outputs of the stepper motor controller 6. Limit switches 7 are connected to the other outputs of the stepper motor controller 6, mounted along the output shaft 4 on each side of the silicon detector case 5. The silicon detector 5 is connected to a two-channel preamplifier 8, the outputs of which connected to operational amplifiers 9 and 10. Each of the outputs of operational amplifiers 9 and 10 has two output amplifiers 11-12 and 13-14, respectively. Output amplifiers 11 and 13 are connected to the inputs of the ADC 18 using a cable delay. Output amplifiers 12 and 14 through comparators 15, 16 of the control and measurement unit 2 are connected to the trigger switch 17. The outputs of the trigger switch 17 through the coincidence circuit 19, the delay line 20 and the circuit "BUSY" 21 are connected to driver 22.

The output of the shaper 22 is simultaneously connected to the programmable logic integrated circuit (FPGA) 24 and through the control circuit 25 to the ADC 18. To the other inputs of the ADC 18 through the control circuit 25 are connected the conclusions from the "BUSY" circuit 21 and the FPGA 24.

The control output of the ADC 18 is connected to the FPGA 24. The controller 23 and the FPGA 24 can be connected for external control via the USB module 26 to the personal computer 27. The power supply of the detector module 1 and the control and measurement unit 2 is made from the corresponding power supplies 28 and 29.

The setup for measuring the composition of the ion beam is used as follows. The detector module 1 and the control and measurement unit 2 are powered from the respective power supplies 28 and 29. To measure the composition of the ion beam in the controller of the stepping motor 6, a leading phase signal is generated to start the linear stepping motor 3 in half-step, normal or oscillatory modes. The speed of movement of the output shaft 4 of the stepper motor is set, the controller of the stepper motor 6 is set to the initial position, the direction of movement is set and the operation of the controller of the stepper motor 6 is set. The linear stepper motor 3 is used to move the detector 5 along a linear coordinate, while supplying the required number of pulses to the controller of the stepping motor 6 set the position of the detector 5 in relative to the beam axis. When the detector 5 reaches one of its extreme positions, one of the limit switches 7 connected to the control circuit of the stepper motor 6 controller is triggered, the stepper motor 3 is turned off and the movement of the detector 5 stops.

When charged particles pass through detector 5, a signal is generated that is proportional to the square of the particle charge. From the detector 5, the signal is sequentially passed through a two-channel pre-amplifier 8, operational amplifiers 9, 10 and output amplifiers 11-14. From the output amplifiers 11, 13, the signal is transmitted through a cable delay of 50 ns to the input of the ADC 18, and from the output amplifiers 12, 14 to the trigger logic of the control and measurement unit 2, containing the comparators 15, 16 connected to the trigger switch 17.

In the mode of determining the zero position of the output amplifiers 11-14 and picking up the noise characteristics of the detector 5, the trigger switch 17 disconnects the outputs of the comparators 15, 16 from the coincidence circuit 19, and the input of the coincidence circuit 19 is connected to the controller 23 pulse generator.

In the measurement mode, the trigger switch 17 connects the required number of comparators 15, 16 to the input of the coincidence circuit 19, while in case of failure of one of the trigger channels, the trigger switch 17 disconnects the idle channel from the input of the coincidence circuit 19 and continues to work with the remaining ones.

In the presence of a predetermined number of signals exceeding the threshold of the comparators 15, 16, the coincidence circuit 19 allows the further passage of the signal to the delay line 20, where the trigger signal is synchronized with the signal of the detector 5. Then the signal is transmitted to the "BUSY" circuit 21, and if at the moment the ADC 18 is not is busy processing the previous pulse, the signal is transmitted to the shaper 22, in which a pulse with a duration of 80 ns to 400 ns is generated, allowing the integration of the input signal of the ADC 18 and triggering the FPGA 24.

At the end of the integration pulse of the input signal from the shaper 22, the FPGA 24 sends a "storage" signal to the ADC 18, while, to reduce the noise level, the signal at the beginning of the conversion of the input signal is delayed relative to the "storage" signal by 200 ns. After the end of the conversion, the FPGA 24 reads data from the ADC 18 simultaneously from all channels, converts the received serial code into parallel and writes the result to the USB module 26. After recording the result, the control and measurement unit 2 goes into standby mode. From the USB module 26, the digitized signal is transmitted to the IBM PC 27 for final processing and visualization of the signal amplitude in the form of a histogram of the signal amplitude distribution.

The technical result is an increase in the accuracy of measurements of the energy characteristics of the ion flow, is achieved due to the fact that the preliminary 8, operational 9, 10 and output 11-14 amplifiers are connected in series to the analog output of the detector 5, while the operational amplifiers 9, 10 are connected according to the integrator scheme, the pulse formation time in which is selected based on the expected detector load no more than 10 ⁶ particles per reset / detector, and two output amplifiers 11-14 are connected to each of the outputs of the operational amplifiers 9, 10, increasing the amplitude of the useful signal in relation to the noise level, and the delay line 20 of the analog signal of the detector 5 provides a signal delay from 11 to 266 ns, as a result of which the noise level decreases when the inverted and delayed signals are superimposed. In this case, the placement of the detector 5 on the output shaft 4 of the linear stepper motor 3 controlled by the controller of the stepping motor 6 provides a more accurate position of the detector 5 relative to the measured ion beam, thereby increasing the level of the output signal of the detector 5.

Claims (3)

1. Installation for measuring the composition of the ion beam, containing a detector, characterized in that the detector is mounted in a detector unit enclosed in a metal case with an entrance and exit window for the passage of particles, while the detector is located across the ion beam on the output shaft of the stepper motor, the detector is made in the form of four pad elements made of silicon, the detector is controlled by a stepper motor controller, on the sides of the detector in the detector unit along the axis of movement, limit switches are mounted with the ability to limit the linear movement of the detector, a preliminary, operational and output amplifiers are connected in series to the analog output of the detector. 2. An installation according to claim 1, characterized in that the detector unit is configured to connect and transmit a signal to the control and measurement unit via a cable communication line for data transmission in such a way that the output amplifiers of the detector unit are connected simultaneously to the ADC and to the comparators of the control unit and measurements, while the output amplifiers are made with the ability to connect to the ADC through the delay cable, the comparators are connected to the trigger switch, the outputs of which are connected through the coincidence circuit, the delay line, the "BUSY" circuit and the driver to the programmable logic integrated circuit, to the other input of which is connected ADC, while the information outputs of the "BUSY" circuit, the driver and the programmable logic integrated circuit are connected to the ADC through the control circuit, and the programmable logic integrated circuit is made with the possibility of connecting via the USB interface with the control computer, and the power supply of the detector unit and the control unit and measurement rhenium is made from separate power supplies. 3. Installation according to claim 1, characterized in that the limit switches are included in the control circuit of the stepper motor controller.

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