RU2764047C1 - UNIVERSAL PAYLOAD UNIT FOR CubeSat FORMAT NANOSATELLITES - Google Patents

Abstract

FIELD: space technology.

SUBSTANCE: invention relates to the field of space technology, and more specifically to satellites. A universal payload unit for CubeSat format nanosatellites consists of a sensor and sample module and an associated analytical module. The analytical module includes a microcontroller connected by direct and feedback links to an on-board computer, a multiplexer and an input amplifier, a permanent storage device, as well as a real-time clock and a reference voltage source. The microcontroller is additionally connected by direct and feedback links to an auxiliary microcontroller. The latter is connected by direct and feedback links to an additional permanent storage device. The on-board computer is additionally connected by direct and feedback links to a receiving and transmitting device and a power module. An output of the power module is connected to an input of the reference voltage source.

EFFECT: increased reliability is achieved.

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Description

The invention relates to space technology, namely to devices for conducting scientific research on board CubeSat format nanosatellites. The device allows to study the electrical properties of new devices of micro- and nanoelectronics in space.

A known method for assessing the resistance of digital electronics to the effects of failures from exposure to single particles /1, patent RU 2657327 C1/. The invention relates to methods for testing semiconductor devices for resistance to heavy charged particles of various energies of outer space. Also known is a method for assessing the resistance of digital electronic equipment to the effects of ionizing radiation 12, patent RU 2578053 C1/. The invention relates to the field of research into the radiation resistance of semiconductor devices (SPP) and integrated circuits, and to a greater extent integrated circuits (IC), with sequential and combinational processing of logical signals. These methods affect only a part of the space factors that affect the properties of semiconductor devices. However, the most effective way, taking into account the influence of all factors, is to study the operation of micro- and nanoelectronic devices directly in space. A device and method for studying the impact of outer space factors on substances and microorganisms /3, patent RU 2603817 C1/ by exposing these objects in outer space and returning them after exposure to Earth for research is known. Here it is proposed to return research objects to Earth, which requires the involvement of additional technical and financial resources.

The closest analogue of the invention is a universal payload platform for small satellites of the CubeSat standard, information about which is published in the journal Izvestiya vuzov /4, Instrumentation. T. 61, No. 5. 2018 ("Universal payload platform for small satellites of the CubeSat standard" / D.V. Fomin, D.O. Strukov, A.S. German // Bulletin of universities, instrumentation. T. 61, No. 5. 2018. - С 185-189 DOI 10.17586/0021-3454-2018-61-5-446-449)/. The platform includes: a control AVR microcontroller, a read-only memory device for temporary data storage, a multiplexer for connecting sensors, an input amplifier, a voltage stabilizer, a real-time clock, and a reference voltage source. This payload platform is designed for university students to conduct scientific experiments on the study of new micro- and nanoelectronic devices, testing prototypes of semiconductor devices and for remote sensing of the Earth.

The technical problem solved by the invention is to create a universal payload unit for nanosatellites of the CubeSat format for semiconductor device developers to study the influence of space factors on the electrical properties of micro- and nanoelectronic devices in near-Earth orbits without returning them to Earth. The device must meet increased requirements for reliability when using complex programming algorithms, high fault tolerance, and the ability to explore a wide range of devices.

The need to solve such a technical problem is dictated by a limited number of devices that maximally simulate the factors of outer space (several units in the Russian Federation) for the study of new semiconductor devices intended for the space industry, while one launch of a carrier rocket with a passing load can deliver 30-40 nanosatellites with samples and conduct in situ studies.

In our invention, the study of the impact of space factors on samples is carried out directly in space.

The device consists of two modules made on separate boards. The larger analytical module contains a system for controlling, analyzing and interacting with external devices. The smaller module contains sensors and test samples and is connected to the first module by an independent bus.

The difference from the closest analogue is:

1. The ability to apply more complex programming algorithms by using a 32-bit STM microcontroller as the main microcontroller (MC) instead of an 8-bit AVR microcontroller.

2. In increasing the fault tolerance of the device by adding an auxiliary microcontroller (AMC) and read only memory (ROM2) with a backup copy of the main microcontroller program, for reprogramming the latter in the event of a software failure in orbit.

3. In expanding the amplitude spectrum of input signals processed by the MC by introducing low-noise operational amplifiers with electronically controlled gain.

4. In optimizing the composition of the universal payload unit by eliminating the voltage stabilization system from it, which duplicates the operation of the nanosatellite's voltage stabilization system.

The essence of the invention lies in the fact that in a universal payload unit for nanosatellites of the CubeSat format, consisting of a module of sensors and samples (S&S) installed outside the nanosatellite body on the mounting panel, and an analytical module connected to it by a flexible cable, installed inside the nanosatellite body according to the standard RS/104, which includes a microcontroller (MC) connected by direct and feedback to the on-board computer (BC), multiplexer and input amplifier (UMiU), read-only memory (ROM1), as well as a real time clock (RTC) and a reference voltage source ( ION), the outputs of which are connected to the inputs of the microcontroller, the microcontroller (MC) is additionally connected by direct and feedback connections with an auxiliary microcontroller (AMC), which, in turn, is connected by direct and feedback connections with an additional read-only memory device (ROM2), and the on-board computer additionally connected by direct and feedback to the receiving-transmitting device ohm (PPU) and power supply module (MP), the output of the latter is connected to the input of the reference voltage source (ION).

In this device, the implementation of the block diagram is built using: an STM32 type microcontroller, which controls the process of collecting and primary data analysis, which is responsible for interaction with the onboard computer of the nanosatellite; an auxiliary microcontroller and read-only memory (ROM2) with a backup copy of the main microcontroller program for reprogramming the latter in the event of a software failure in orbit; low-noise operational amplifiers with electronically adjustable gain to enable the MC to operate with a wide range of input signal amplitudes; scaling multiplexers to implement a change in the number of sensors and/or samples depending on the objectives of the experiment; a developed system of interfaces to ensure the connection of the payload to various types of on-board computers using the UART, SPI, I2C protocols, etc.; read-only memory (ROM1) for long-term storage of experimental data; real time clock for synchronization of measurements; reference voltage source to ensure measurement accuracy.

The device is shown in the following drawings: FIG. 1 is a general view of a CubeSat 3U format nanosatellite with an installed universal payload unit, FIG. 2 is a view of the analysis module (larger) and sensor and sample module (smaller) of the universal payload unit, FIG. 3 is a block diagram of a universal payload unit as part of a nanosatellite, FIG. 4 - mounting panel for the module of sensors and samples.

The proposed unit is installed in the nanosatellite in the following way (see Fig. 1): the sensor and sample module 1 is placed on the outer side of the CubeSat 3 format nanosatellite housing using the mounting panel 4 flush with its edge, while the analytical module 2 is located inside the housing 3 , in the same place where the service units of the nanosatellite are located. Between themselves, the modules of the payload unit are connected by a flexible cable (see Fig. 2).

The block diagram (see Fig. 3) defines the main functional parts of the device, their purpose and relationships. The abbreviations on the block diagram of the device mean: MDIO - a module of sensors and samples, UMiU - a device for multiplexing and amplifying signals, MK - the main microcontroller, ROM1 - read-only memory No. 1, VMK - auxiliary microcontroller, ION - reference voltage source, RTC - real clock time, ROM2 - read-only memory No. 2, BC - on-board computer of the nanosatellite, PPU - receiving-transmitting device, MP - power supply module.

The device works as follows.

The Sensors and Samples Module (see Fig. 3 hereinafter) or M&O, contains samples of micro- and nanoelectronic devices under study, as well as sensors (their number and type are determined by the conditions of the experiment). The signals from the samples and sensors are fed into the signal multiplexing and amplification device (UMiU), where they are selected and amplified in amplitude to levels sufficient for analysis by the main microcontroller (MC). The microcontroller controls the process of data collection and primary analysis, their sorting, and the formation of a frame for interaction with the onboard computer (BC) of the nanosatellite. The data is marked with the help of a real time clock (RTC), read by the onboard computer (BC) of the nanosatellite and sent to Earth using a receiving-transmitting device (RTD).

In the event of a failure of the program code of the main MC, it is reprogrammed directly in orbit using an auxiliary microcontroller (AMC) and a backup copy of the MC program stored in ROM2. The accumulation of experimental data and their long-term storage is carried out in ROM1, from which arbitrary unloading of data is possible upon request from the Earth. The accuracy of the experiments is maintained by a reference voltage source (RPS), which is connected to the power supply module (MP) of a small spacecraft.

The technical result of using the utility model is that it allows developers of semiconductor devices to study the influence of space factors on the electrical properties of a wide range of micro- and nanoelectronic devices directly in space on the CubeSat format nanosatellite platform without returning them to Earth. The ability to apply complex programming algorithms when setting up experiments, as well as their reliability due to the increased fault tolerance of the model.

List of sources used:

1. Patent No. 2657327

2. Patent No. 2578053

3. Patent No. 2603817

4. "Universal payload platform for small satellites of the CubeSat standard" / D.V. Fomin, D.O. Strukov, A.S. German // Izv. universities, instrumentation. T. 61, No. 5. 2018. - S. 185-189. DOI 10.17586/0021-3454-2018-61-5-446-449

Claims (1)

A universal payload unit for CubeSat format nanosatellites, consisting of a sensor and sample module installed outside the nanosatellite body on the mounting panel, and an associated analytical module installed inside the nanosatellite body according to the RS / 104 standard, including a microcontroller connected by direct and feedback with an on-board computer (BC), a multiplexer and an input amplifier, a permanent memory, as well as a real-time clock and a reference voltage source, the outputs of which are connected to the inputs of the microcontroller, characterized in that the microcontroller is additionally connected by direct and feedback with an auxiliary microcontroller, which, in in turn, is connected by direct and feedback to an additional permanent storage device, and the on-board computer is additionally connected by direct and feedback to the transceiver and power module, the output of the latter is connected to the input of the reference voltage source.

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