RU61906U1 - SYSTEM OF ACCOUNTING, MONITORING AND FORECAST IN ACCOMPLISHING ACTIONS WITH RESOURCES - Google Patents

Abstract

The utility model relates to systems for monitoring processes associated with the use of metrological measurement resources (measurement resources), the system is intended to take into account the resources included in and from it, as well as to monitor and predict their accumulation, movement in the system, and provide a numerical-graphic forecast result state of resources for monitoring and decision making.

The system of accounting, control and forecasting when performing actions with resources consists of a data input device for the first moment of time with two inputs, consisting of a block of the planned value of the resource with one input and output, a block of the actual value of the resource with input and output, and the output of the block of the planned value the resource and the output of the unit of the actual value of the resource are connected to two inputs of the unit for calculating and comparing parameters, and the output of the comparison unit is connected to the unit for recording differences in the values of resources and the unit is stored resource, its output is connected to one of the inputs of the unit for selecting and fixing the values of the resource, and the data input device at the second moment of time, consisting of a block of the planned value of the resource and a block of the actual value of the resource, the outputs are connected respectively to the inputs of the blocks of the planned value of the resource and the actual value the resource of the data input device at the first moment of time, and the output from the unit for calculating the planned value of the resource according to the given conditions of the device, data input at the first moment of time is connected with a block of the planned input device resource

data at the second point in time. An additional device for monitoring numerical and graphic forecast data, a device for predicting the state of a resource, which consists of blocks for forecasting a measured resource and a forecast for a planned resource, are added to the system, the outputs of these blocks are connected to a monitoring device for numerical and graphic forecast data, and the inputs of these blocks are connected to the output of the block the planned value of the resource and the output of the block of the actual value of the resource of the data input device at the first moment of time, moreover, the data device at the first moment the resource standardization unit was additionally introduced according to the measurement model of the object with the input and the first output connected to the resource selection and fixing unit, and the second output of the unit connected to the second input of the resource state memory unit discrete in time of the data input device at the second time moment, and the output of the unit the resource status memory is connected to the memory unit of the actual value of the resource of the data input device at the second time moment.

The proposed system allows predicting the health of the driver of the vehicle to achieve the main practical goal - determining the present and future health status of the driver of the vehicle relative to the boundary conditions of the “high-risk group for the possibility of pathological changes, sudden deterioration in well-being and inadequate response.

Description

The utility model relates to systems for monitoring processes associated with the use of metrological measurement resources (measurement resources), the system is designed to take into account the resources entering into and outgoing from it, as well as to monitor and predict their accumulation, movement in the system, and provide a numerical-graphic forecast result state of resources for monitoring and decision making.

A known system of accounting, planning and control when performing actions with resources. The system includes a unit for inputting a task to the system at a given moment in time, a unit for inputting values at another moment of time, of interest to the user, a memory unit, means for calculating the set values, and control means (US, 5523942 A, G 06 F 157/00, 06/04/1996). The system combines a basic computer system and a user interface to enter the system and provide information on insurance and deposits.

The disadvantage of this system is the limited scope due to the use in each case of a specific processing algorithm, as a result of the development of a unique program. The system only processes data on monetary resources and does not have the ability to control itself, for example, how money - goods - money, or goods - money - goods, or energy - transferring in one direction or another, etc. Known analogues are difficult to use, in a known system it is difficult to trace in time the process of conducting an operation to convert the input parameters that are planned and actually obtained through

any selected period of time.

There is a known system for monitoring processes associated with the use of various kinds of resources (financial, energy, commodity, etc.), the system is designed to take into account the resources both entering and leaving it, plan and control their movement in the system (RU, 2137198 C1, G 06 F 19/00, G 07 C 3/14, G 06 F 17/60 // G 06 F 157: 00, 09/10/99, Bekrenev Vitaliy Leonidovich). The system is designed to ensure accounting of parameters (resources) entered into the system during their conversion, transfer of resources under the planned condition (percentage) to obtain a result when moving a resource, control over the return of resources to the system or transferring it from the system, control over obtaining actual income (expense) ) The system also provides debt accounting for non-receipt of income, debt accounting for the return of a resource, and these indicators can be determined at any given point in time. The system allows you to take into account, plan and control (promotion) actions with different types of resources: cash, mining, selling energy resources, moving material resources within a separate workshop, enterprise, industry, region, converting resources into a control system for regulatory processes, for example, fuel consumption consumption and production of electricity, consumption and production of substances, etc. depending on the indicators entered into the system and indicators that need to be controlled. In addition, at each cycle of the system, defined between the time T1 for entering the task and the time T2 planned for monitoring the execution of the task, indicators are determined for monitoring and accounting for the state of the resource in the system, while the system can control the processes until full agreement is reached between the planned indicators and the actual by entering 8 in the next cycle of values, taking into account the values obtained in the previous cycle.

The disadvantage of this system is its use only in the areas of classical accounting of assets and liabilities of resources without processing measurement resources, taking into account the number of events according to a certain distribution law, the lack of processing of the dynamics of resource accumulation and modeling functions for forecasting the state of resources.

This technical solution is selected as a prototype.

The technical result of the claimed system is the expansion of functionality through the application of parameter estimation methods for predicting dynamic models of measurement resources.

The technical result is achieved by the fact that in the accounting system, planning and control when performing actions with resources consisting of a data input device at the first moment of time and a data input device at the second moment of time, an additional device for predicting the state of resources and a device for monitoring numerical-graphic forecast data .

To the data input device at the first moment of time, consisting of a unit for selecting and fixing resource values, a unit for calculating the planned resource value under specified conditions, a unit for the planned resource value, a unit for the actual resource value, a unit for calculating and comparing parameters, a unit for recording differences in the resource values and the unit storage of the resource, an additional unit for rationing the resource according to the model of measurements of the object, a connection of the first output of the block for rationing the resource for the model of measurements of the object with the first input selecting the block and fixing the values of the resource, the connection of the second resource unit normalization output of the measurement model object to the input data input device for a second time.

At the second moment in time, which consists of a block of the planned resource value and a block of the actual resource value, a resource state memory block is additionally introduced discretely

in time, the connection of the output of the resource state memory block is discrete in time with the input of the block of the actual value of the resource.

The resource state forecasting device is made from the forecast unit of the measured resource and the forecast unit of the planned resource. In addition, connections have been introduced connecting the output of the block of the planned value of the resource and the output of the block of the actual value of the resource of the data input device at the first moment of time with the input of the forecast block of the planned resource and the input of the forecast block of the measured resource of the resource state forecast device.

The device for monitoring the numerical and graphic forecast data is connected by new connections to the output of the forecast block of the planned resource and the output of the forecast block of the measured resource of the resource state forecast device.

A system for forecasting the state of resources is additionally introduced into the monitoring system for processes associated with the use of various types of resources, which makes it possible to predict the state of measurement resources with a reliable probability by improving the metrological properties of the system by measurement models when receiving information about incoming resources and using dynamic parameter identification methods resource models. Calculation of a signal that is close in probability to useful is performed by a new resource rationing unit according to the object measurement model in the data input device at the first moment in time and comes from the first output to the first input of the resource selection and fixing unit. The second output of the resource rationing unit according to the object measurement model is connected to the second input of the new resource status memory block discretely in time of the data input device at the second time moment. This memory block is the main device for accumulating information about the state of the resource discretely in time to identify the parameters of the dynamic model while providing calculations

according to this model of a device for predicting the state of a resource. The objectivity of observing the resource dynamics is achieved by the introduced device for monitoring the numerical-graphic forecast data connected by new connections to the output of the resource state forecast device. The connection of the resource state forecasting device with the block of the actual value of the resource and the block of the planned value of the resource of the data input device at the first moment of time gives a variant of the forecast of the measured resource as a fact of its future state and a forecast of reaching the value of the measured resource to the planned value. The connection of the output of the resource state memory block is introduced discretely in time and the input of the block of the actual value of the resource of the data input device at the second moment of time, which makes it possible to track the pattern of development of the dynamics of the resource’s receipt in the system and realize the forecast by the time model of the forecast device.

Supplementing the system with new devices, blocks, and connections makes it possible to predict with reliable probability the state of measurement resources and the state of planned indicators for actions with them when the system simulates the dynamics of the receipt and movement of resources with the output of a numerical-graphic result to a monitoring device, which expands the system’s functionality.

Figure 1 - system of accounting, control and forecast when performing actions with resources.

The system (Fig. 1) consists of a data input device 1 at a first time, a data input device 2 at a second time, an input 3 of a data input device at a first time, an input 4 of a data input device at a second time, a state prediction device 5 a resource, a device 6 for monitoring the numerical-graphic forecast data, a unit 7 for normalizing a resource according to an object’s measurement model, a unit 8 for selecting and fixing resource values, and a calculation unit 9

the planned value of the resource under the given conditions, block 10 of the planned value of the resource, block 11 of the actual value of the resource, block 12 for calculating and comparing parameters, block 13 for recording differences in the values of the resource, block 14 for storing the resource, block 15 for the resource status memory is discrete in time, block 16 for the planned the value of the resource, block 17 of the actual value of the resource, block 18 of the forecast of the measured resource, block 19 of the forecast of the planned resource.

The system works as follows on the example of pre-trip examinations, where the resources are measurements of the medical parameters of the health of drivers of vehicles.

At time T1, for example, the numerical data of the medical parameters of the object through the channels of the information-measuring complexes are transmitted through input 3 of the data input device at the first moment of time 1 to the input of block 7, which normalizes measurements according to the static measurement model discretely in time, forming a measurement resource with minimal interference observing the input signal. From the first output 7, the information goes to the first input of the unit for selecting and fixing the value of the resource 8 and from the second output to the second input of the block of memory of the resource states discretely in time 15. The fixed value of measurements of medical parameters from the output 8 goes to the input of the block 9 for calculating the planned value of the resource, in which, under given conditions, by means of mathematical calculations and transformations, the planned value of the medical norm for a given resource is determined and transmitted to the input of block 16 of the planned value of the resource devices 2.

At time T2, the conditions for calculating the forecast come through input 4 of the data input device at the second time 2 to the first input of the resource state memory block discretely in time 15. The first input 15 performs the functions of a controller for the second input, setting the conditions for dynamic modeling, memory depth, period

forecast, etc. From the output of block 15, information about the current and previous state of the measurement resource goes to cell 17 of the actual value of health parameters, in which the actual value of health parameters is fixed, output 17 is connected to the input of block 11 of the actual value of the resource of device 1, the output of block 16 is connected to the input of the block 10 of the planned value of the resource of the device 1. The output of block 10 and the output of block 11 are connected to the input of the block for calculating and comparing parameters 12. In element 12, the main health parameters of the driver are compared critical maximums and minimums of the boundaries of the planned permissible norms, then the result is fed to the input of block 13 fixing differences in the value of the resource with critical norms and to the input of the resource storage unit 14. Output 14 is connected to the second input 8 for working with archived data of normalized measurements or data in the storage unit Information 14 can be used, in the case of the stationary flow of the resource, to correct the characteristics of the stationary flow coming into the system of quantities.

The device for forecasting the state of the resource 5 calculates the dynamics of the resource for the forecast period with the numerical graphic output to the monitoring device 6. The output of block 10 and the output of block 11 of the data input device at the first time 1 connect device 1 to device 5 with the input of the forecast block of the planned resource 19 and the input of the unit 18 of the forecast of the measured resource, respectively. The output of block 18 issues a forecast of the state of health parameters of the driver of the transport to the monitoring device 6 as an assumed fact, the output of block 19 gives the forecast of the state of health parameters of the driver of the vehicle relative to the border conditions of risk groups to the monitoring device 6 when planning health effects by factors of labor or health-improving measures.

The proposed system allows the prediction of driver health

vehicle to achieve the main practical goal - the determination of the present and future state of health of the driver of the vehicle relative to the boundary conditions of the “high-risk group for the possible development of pathological changes, a sudden deterioration in well-being and inadequate response.

Claims (1)

The system of accounting, control and forecasting when performing actions with resources, consisting of a data input device for the first moment of time with two inputs, consisting of a block of the planned value of the resource with one input and output, a block of the actual value of the resource with input and output, and the output of the planned block resource values and the output of the actual resource value unit are connected to two inputs of the parameter calculation and comparison unit, and the output of the comparison unit is connected to the unit for recording differences in the values of resources and the storage unit of the resource, its output is connected to one of the inputs of the block for selecting and fixing the values of the resource, and the data input device at the second moment of time, consisting of a block of the planned value of the resource and a block of the actual value of the resource, the outputs are connected respectively to the inputs of the blocks of the planned value of the resource and the actual value the resource of the data input device at the first moment of time, and the output from the unit for calculating the planned value of the resource according to the given conditions of the device, data input at the first moment of time is connected a unit with a planned resource value of a data input device at a second point in time, characterized in that a monitoring device for numerical-graphic forecast data, a device for predicting a resource state, which consists of blocks for measuring a measured resource and forecasting a planned resource, are additionally introduced into the system, outputs of these blocks connected to the device for monitoring the numerical-graphic forecast data, and the inputs of these blocks are connected to the output of the block of the planned resource value and the output of the actual block the resource value of the data input device at the first moment of time, and at the first moment of time, a resource rationing unit according to the object measurement model with an input and a first output is connected to a block for selecting and fixing the value of the resource, and the second output of the block is connected to the second input of the block the resource status memory is discrete in time of the data input device at the second instant of time, and the output of the resource status memory block is connected to the memory block of the actual value of the resource of the input device data at the second point in time.