WO2000065418A2 - PROCEDE ET AUTOMATISME DE REGULATION D'UNE PRODUCTION INDUSTRIELLE ETAGEE AVEC MAITRISE D'UN STRESS ENCHAINE ALEATOIRE, APPLICATION AU CONTROLE DU BRUIT ET DU RISQUE VaR D'UNE CHAMBRE DE COMPENSATION - Google Patents
PROCEDE ET AUTOMATISME DE REGULATION D'UNE PRODUCTION INDUSTRIELLE ETAGEE AVEC MAITRISE D'UN STRESS ENCHAINE ALEATOIRE, APPLICATION AU CONTROLE DU BRUIT ET DU RISQUE VaR D'UNE CHAMBRE DE COMPENSATION Download PDFInfo
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- WO2000065418A2 WO2000065418A2 PCT/FR2000/001059 FR0001059W WO0065418A2 WO 2000065418 A2 WO2000065418 A2 WO 2000065418A2 FR 0001059 W FR0001059 W FR 0001059W WO 0065418 A2 WO0065418 A2 WO 0065418A2
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q40/00—Finance; Insurance; Tax strategies; Processing of corporate or income taxes
- G06Q40/02—Banking, e.g. interest calculation or account maintenance
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- G—PHYSICS
- G05—CONTROLLING; REGULATING
- G05B—CONTROL OR REGULATING SYSTEMS IN GENERAL; FUNCTIONAL ELEMENTS OF SUCH SYSTEMS; MONITORING OR TESTING ARRANGEMENTS FOR SUCH SYSTEMS OR ELEMENTS
- G05B19/00—Programme-control systems
- G05B19/02—Programme-control systems electric
- G05B19/418—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS], computer integrated manufacturing [CIM]
- G05B19/41865—Total factory control, i.e. centrally controlling a plurality of machines, e.g. direct or distributed numerical control [DNC], flexible manufacturing systems [FMS], integrated manufacturing systems [IMS], computer integrated manufacturing [CIM] characterised by job scheduling, process planning, material flow
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q10/00—Administration; Management
- G06Q10/06—Resources, workflows, human or project management; Enterprise or organisation planning; Enterprise or organisation modelling
- G06Q10/063—Operations research, analysis or management
- G06Q10/0631—Resource planning, allocation, distributing or scheduling for enterprises or organisations
- G06Q10/06312—Adjustment or analysis of established resource schedule, e.g. resource or task levelling, or dynamic rescheduling
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- G—PHYSICS
- G06—COMPUTING; CALCULATING OR COUNTING
- G06Q—INFORMATION AND COMMUNICATION TECHNOLOGY [ICT] SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES; SYSTEMS OR METHODS SPECIALLY ADAPTED FOR ADMINISTRATIVE, COMMERCIAL, FINANCIAL, MANAGERIAL OR SUPERVISORY PURPOSES, NOT OTHERWISE PROVIDED FOR
- G06Q10/00—Administration; Management
- G06Q10/06—Resources, workflows, human or project management; Enterprise or organisation planning; Enterprise or organisation modelling
- G06Q10/063—Operations research, analysis or management
- G06Q10/0637—Strategic management or analysis, e.g. setting a goal or target of an organisation; Planning actions based on goals; Analysis or evaluation of effectiveness of goals
- G06Q10/06375—Prediction of business process outcome or impact based on a proposed change
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
- Y02P90/00—Enabling technologies with a potential contribution to greenhouse gas [GHG] emissions mitigation
- Y02P90/02—Total factory control, e.g. smart factories, flexible manufacturing systems [FMS] or integrated manufacturing systems [IMS]
Definitions
- the present invention relates to a method and a device (automation) for regulating and / or preventing rupture of a multi-stage and multi-link industrial production flow F of the type aiming: - to optimize the production flow F (r ) by acting on an industrial action parameter (r),
- industrial production or production
- production flow any human activity having as its object the production of added value (production flow)
- production flow F (r) we mean, according to invention, any transfer of material or measurable quantity emitted at the final stage E propeland originating from the sequence of production activities of the production sub-assemblies S ⁇ at the different stages E, of the production cycle.
- the invention relates to the industrial, manufacturing and financial fields, where it is necessary to estimate, in order to circumscribe it, a random impact I (r), which can be of either the manufacturing (nuisance) or financial (risk of loss and / or bankruptcy), and which is linked to the exercise of value added production (manufacturing or financial production).
- a random impact I (r) which can be of either the manufacturing (nuisance) or financial (risk of loss and / or bankruptcy), and which is linked to the exercise of value added production (manufacturing or financial production).
- the overall aim sought is to optimize the flow of value added production while limiting a negative random impact linked to this production.
- This random impact I (r) is generally found to increase with the volume of this production of added value.
- the invention is implemented specifically in the case of a production with a multi-stage and multi-link configuration.
- the structure of this production can be either tree-like or, in the more general case, matrix.
- the invention consists in regulating production according to a process of the probabilistic automatism type with an action loop and a feedback loop.
- this automatic regulation can be carried out electronically using a programmed and wired computer to carry out the steps of the method according to the invention, as described below.
- the outputs of the computer are then transmitted to a servo system or servomotor acting on the industrial action parameter (r) to assign it its optimal value.
- the action loop of the automation consists of a simulator of probabilistic inductive evaluation of the chain of stresses random in the production chain leading to a probabilistic measure of the resulting industrial impact I (r), this as a function of the "adjustable" level of the industrial action parameter (r).
- the method implemented by the invention, within the action loop of the automation is generally called “Value at Risk” or “VaR”.
- the VaR method is currently used mainly in the financial sector, with a view to understanding quantifiable market risks (volatility of the value of a portfolio of securities), as well as credit and liquidity risks in financial institutions.
- the level of the industrial action parameter (r) is adjusted over time (t) to the multivariate extreme value (rmax ) or (rmi n ), by keeping said effect estimator VaR (p, T) (r) below its authorized nuisance level M.
- VaR the amount, noted VaR such as the loss incurred on this portfolio during the time horizon T- [0, t] will only exceed VaR with a probability equal to (lp).
- Prob [loss on portfolio> VaR] Xp, this probability being calculated according to a supposed distribution of external sub-hazards Xj (volatility of market prices) influencing the portfolio.
- the first method of estimating VaR is called the matrix of estimated variances-covariances, initially developed by the company JP Morgan (see JP Morgan, RiskMetrics TM - Technical documents, 4 * ed., Morgan Guaranty Trust Company, New York , 1996). This method is almost not applicable and / or very imprecise in the case of application to complex assets (implied volatility of options).
- the second VaR estimation method known as historical analysis, was initially advocated by the company Chase Manhattan, with the Charisma TM and Risk $ TM systems. (see CHASE MANHATTAN BANK N.A, Value at Risk, 1996). It is based on the assumption of the stationarity of risk factors. Besides the fact that it presupposes that the future behaves statistically identical to the past - and more precisely, to the recent past - it has a strong tendency to misjudge the frequency of catastrophic events. In addition, the historical VaR method cannot technically simulate the total failure of one stage of the risk process.
- the third VaR estimation method called Monte-Carlo simulation, was initially advocated by the company Bankers Trusts, with its RAROC 2020 TM system.
- the invention measures the random industrial impact I (r) resulting from random chained stresses in the production subsystems S tJ at the different stages of production, according to the third method, that is to say by Monte-Carlo Simulation.
- a system of the type according to the invention applies to a multi-stage and multi-link clearing house, that is to say taking into account several stages of fault reporting: the initial stage of customers d '' a member, or subsidiaries; then the floor of the members (stockbrokers) themselves ...
- the systems of the prior art either are single-stage and only consider the member accounts, or are multi-stage but only perform a simple merger of the member and customer accounts in their probability calculation. In other words, the systems of the prior art which consider a tree structure of counterparts (consisting of productive sub-assemblies distributed in stages) are satisfied with calculating the simultaneous defect of each branch of the "tree".
- While the invention measures the inductive probabilistic sequence of defects in the branches of the "tree” with probabilistic calculation at each of the levels. More generally, the systems of the prior art, unlike the invention, do not take into account the measurement of the "catastrophic" probabilistic sequence of stresses at the level of several stages of production.
- This system simulates the portfolio in a first reduced Monte-Carlo, then calculates a simplified portfolio with similar behavior.
- Moody's TM therefore are fixed, are not determined in a probabilistic manner and do not depend on market movements.
- the "VaR Credit” of several counterparties are added up, not merged by inductive method of probabilistic sequence of defaults. ⁇ CreditRisk + TM by Mark Holmes
- This multi-stage system recommends taking into account a probability of default for the sub-systems of a stage, which is not fixed. But the process chosen is a random process. That is to say that the probabilities of default of the productive subsystems S, j do not depend on the aggregate stresses W ZtiJ that they undergo (nor indirectly on the vagaries X and, in this particular case, not on market movements ). In particular, they are not higher when the aggregate stresses W Z ⁇ ij are greater.
- This system proposes to combine the possible defects of the different counterparties to calculate the diversification efficiency of the portfolio. However, it does not propose a probabilistic measurement of faults at the different stages and the sequence of faults between stages by inductive method. ⁇ CATS / Carma TM by Robert Geske
- This system recommends a multi-period Monte-Carlo drawing of market movements, then the passage of counterparties from one "rating" class to another, and finally any default.
- the credit VaR is calculated on each counterparty, broken down by maturity.
- This system does not recommend the aggregation of the risk of counterparty default by inductive probabilistic method, nor the probabilities of default depending on the state of stress (market movement).
- the failure of the various subsystems is not simulated by inductive probabilistic method from stage to stage. That is to say that the prior art does not simulate the fault of the system on the lowest stage 1, and does not report this fault on the level of stage 2, before simulating probabilistically the fault floor 2 subsystems, and so on.
- the probability distribution of the default coefficient of a subsystem S / ⁇ 7 is neither constant nor random, it depends on the 'state of stress of the subsystem S, j , therefore of the state of the market.
- the value of this coefficient is random, of course, according to this distribution.
- the systems of the prior art consider that the reliability of the transmitters is given by their "rating "Moody's TM or S & P TM.
- the systems of the prior art do not involve the quality of the transmitter and its size separately.
- the only way to take into account the size of a transmitter is to consider that the one which is small but reliable, has a very low probability of default for a small amount, but which increases suddenly from a certain amount, while that which is large but unstable has a probability of default of the same order of magnitude for a small amount and a large amount.
- the probability of default is considered to be independent of the amount to be paid, therefore this distinction would be pointless.
- the prior art does not propose to implement, in the probabilistic simulation implemented, random disaster scenarios, with given probabilities .
- the prior art generally proposes to carry out "stress tests" the aim of which is to study the consequences of a catastrophic movement such as a stock market crash. To do this, he recommends simulating a disaster scenario in which all the parameters are entered by the user, without any risk in these parameters. Certain compensation phenomena ("hedging") can then go unnoticed, which will not be the case if the "stress test” is itself random (such as according to the invention).
- This so-called “close-out netting module” system calculates the commitment on each of the counterparties, taking into account a tree structure of the counterparties.
- the engagement at a level of the "tree” generates the “netting” of all the branch which it carries.
- This system neither advocates the aggregation of the risk of counterparty default by inductive probabilistic method, nor the probabilities of default depending on market movements. This system therefore does not recommend the characteristic means of the invention. o Richard Sandor's Hedge TM
- This system performs a Monte Carlo draw of market movements, then a calculation of the effect on the portfolios and finally a default draw by counterparty independent of the market movement and a calculation of overall VaR.
- This system therefore does not recommend the characteristic means of the invention, ⁇ KMV "EDF" TM by Oltech Vasicek
- This system is based on a "Markov" chain. It evaluates by a multi-period Monte-Carlo method, the expectation of return on a security. This system only takes into account loans or bonds and calculates the risk relating to the issuer. This system assesses the counterparty risk by counterparty. The default probabilities of the subsystems are fixed. This system recommends neither the aggregation of the risk of counterparty defaults by inductive probabilistic method, nor the probabilities of default depending on the state of stress (market movements). This system therefore does not recommend the characteristic means of the invention. ⁇ Midas Kapiti TM from Misys (UK)
- This system recommends neither the aggregation of the risk of counterparty defaults by inductive probabilistic method, nor the probabilities of default depending on the state of stress (market movements). This system therefore does not recommend the characteristic means of the invention.
- ⁇ FEA TM by Mark Garman ⁇ FNX TM by Farid Naib ⁇ Lombard Risk TM by John Wisbey ⁇ RAROC 2020 TM by Bankers Trust ⁇ Summit TM by Jean de Fontenay o Zoology TM by Kenneth Garbade ⁇ Open Link TM by Coleman Fung
- the object of the invention (method and probabilistic automatism of flow control at random chained stress) as described below can be used in many industries as well manufacturing, financial, as 'agricultural.
- the invention is described below, first of all in its overall definition and characterization, that is to say applicable in particular to all types of manufacturing and financial production under chained stress. Then the invention is described more specifically for one of its industrial manufacturing applications (optimization of the production of a factory with noise limitation). Finally, the invention is described for a particularly advantageous application in the finance industry, aimed at optimizing the level of activity of a clearinghouse - stock market of "securities" or commodities - exposed to risks. default of its counterparties (linked to the volatility of the securities markets) and having to comply with global risk limitation criteria - "Capital adequacy" - in order to minimize the risk of bankruptcy.
- the method and the device of the invention can also be implemented for the measurement and control of chained industrial operational risks, in particular in industries whose operation generates certain nuisances such as noise or pollution; as well as in complex industrial systems with a catastrophic chain of risks such as nuclear power plants; drilling platforms (gas and oil) and chemical plants ...
- the provisions of the invention can also be advantageously implemented in the field of agriculture, in particular for the control of the supply cycles of a country or of a region according to the random hazards linked to production (regional or global) and variations in food consumption, while ensuring a minimum intake for each inhabitant.
- FIG. 1 schematically represents the general organization of an industrial production unit for which the implementation of the process and production control device according to the invention is recommended.
- FIG. 2 shows in general form the different stages of implementation of the production control process and the features of the probabilistic automatic regulation according to the invention.
- FIG. 3 shows schematically, the organization of a factory to implement the method and the control device according to the invention, in order to optimize production, while nevertheless controlling that the internal noise at the factory is below a regulatory level.
- FIG. 4 represents, according to the invention, the different stages of implementation of the method and the particularities of the automatic control of production of the factory and of noise reduction of FIG. 3.
- FIG. 5 shows schematically the organization of a clearing house (stock exchange) to implement the probabilistic process and automatic control according to the invention in order to maximize the volume of transactions (and therefore the brokerage fees collected ) while keeping the overall risk of financial loss (linked to the default of members) below a regulatory limit.
- a clearing house stock exchange
- FIG. 6 represents the various stages of implementation of the method and the particularities of the probabilistic automatic control system of the invention for the compensation chamber of FIG. 5.
- FIGS. 1 and 2 describe the general configuration of a system (1) industrial or financial production to allow the implementation of the method and device of the invention.
- the invention is specifically applied to a production of the random chained stress type W, j resulting in an industrial impact I (X, T) (r) (generally harmful), possibly multivariate (I) - (I ⁇ , .., Ih,., L) -
- This impact I (X, T) (r) must be controlled (in particular to avoid breaks or for regulatory reasons) in a time horizon T. It is the result of a cascading sequence of aggregated stress W XJ (measurable phenomena) undergone by each of the productive subsystems S ⁇ .
- the invention relates specifically to the types of production whose industrial impact
- I (X, T) (r) globally monotonous (increasing or decreasing) depends on the aggregated stresses W tJ of the subsystems S ⁇ at the different production stages E provokeand where at least one of the elementary impact components I n depends: a) on the aggregate stresses W mj of the subsystems S mj of the last stage of production E m , aa) on a multivariate environmental factor of production hazard (X) (X I , ..., X N ), each of the X, being called sub-factor of production hazard, aaa) of the time horizon T, aaaa) and globally monotonous (increasing or decreasing, in the same direction as with respect to the aggregated stresses W mj ) of the industrial action parameter (r) via the aggregated stresses W mj .
- Each random aggregated stress W tJ (local "catastrophic" effect) undergone by a subsystem S tJ is in nominal mode, contained at the level of the subsystem S tJ . But it can, in fault mode, be partially or completely transmitted to the next stage E, +1 .
- each aggregated stress W, j is the result (sum): b) on the one hand, of a random stress w tJ specific to the productive subsystem S, and dependent - so known and specific to the subsystem - of the multivariate environmental factor of production hazard (X) as well as globally monotonic (increasing or decreasing) of the industrial action parameter (r), bb) on the other hand, stress transmitted random w ' ⁇ coming from the combination of defects of some of the productive subsystems S, - k of the previous stage E t - ⁇ . as a result of the stress they experienced themselves.
- each of the transmitted stresses w ' tJ ⁇ is expressed as the combination
- Pr, j (X, T, r, W l: J a t J of each of the productive subsystems S is known. It is expressed by an electronic behavior modeling device (2). This behavior modeling (2) complements the probabilistic automaton (3) interfaces with the operator of this automatism (3).
- the multi-bond configuration (of the stress sequence) of the production can be:
- the production control method according to the invention is specifically implemented in the case where the variations, over the time horizon T, of the sub-hazards X, constituting said multivariate factor X of environmental hazard, are quantifiable by a joint probability law V ⁇ ob (x ⁇ , ..., XN).
- the xs constitute the generic state that the sub-hazard X can take, the characteristics of which, in particular, mean, variance and correlations as well as extreme behaviors, result from the statistical analysis of a record history of sub-hazards X,.
- the behavior modeler (2) of the automation (3) electronically generates the joint probability law according to the records of the histories of the sub-hazards stored inside the auxiliary memory area (4) of the histories of the automation (3) and supplies it to the generator
- the invention is finally implemented in the case where the elementary impact components I ft (X, T) (r) of said industrial impact I (X, T) (r) of the production flow F (r) must not exceed, either upwards (type 1) or downwards (type 2), nuisance levels M n , this with a probabilistic industrial reliability P ⁇ ob [I h (X, T) ( r) ⁇ M h ]> p h (type 1), or Pvob [I h ( X, T) (r)> M h ]> p h (type 2). Said nuisance levels M h and the probabilities p n are imposed in particular by regulation or by requirements of the breaking threshold and taken into account in a memory area (9) known as operator specification, belonging to the automation (3).
- the function of the action loop (5) of the production control automation (3) is to calculate electronically, always for the time horizon T, and this as a function of the possible values of the level of the action parameter.
- the level of the parameter d is automatically adjusted over time, within the reaction loop (6) of the production control automation (3).
- the reaction loop (6) of the automation (3) electronically extremes VaR ⁇ ⁇ , 7 r ma or min ⁇ Mh (type 1), or VaR h (ph, T) (r ms or doctrine,, deliberately)> M plausible(type 2).
- the method of the invention also consists in sampling the state of production according to a pseudo-random method of the "Monte-Carlo" type, the overall number of prints of which is Z. This is carried out by the generator from Monte-Carlo (8).
- the method of the invention generally consists in implementing the following known steps, this electronically inside the modeler (2) and the action loop (5) of the automation (3): £)
- a simultaneous behavior model Prob x ⁇ , ..., x / ⁇ i
- Prob x ⁇ , ..., x / ⁇ i
- XJ sub-factors production hazard
- it can be in particular normal, log-normal laws, or more generally a distribution of the levels of the production hazard sub-factors (XJ justified from observations in particular history of these hazards) and transmit it to the action loop (5).
- PCA principal component analysis
- a new main characteristic of the method and device (automatism) (3) of control recommended by the invention consists in that, to electronically generate the elementary impact components I h (x z , T) (r) corresponding to each sample of the hazard x z , we determine electronically for each pseudo-random sample of said multivariate hazard factor (xj, and this as a function of the industrial action parameter (r), the level of the aggregate stresses W ⁇ of each of the sub -productive systems Sy by an inductive probabilistic method (11) starting from the first stage E ⁇ towards the last E m .
- a pseudo-random generation is effected electronically of said default coefficient d ⁇ i of each of the productive subsystems S ⁇ of stage E ⁇ , according to said distribution of probability of elementary default P ⁇ ⁇ j (x z , T, r, W Z ⁇ ⁇ j , ⁇ i j ) of the productive subsystem S 1 (/ , as supplied by the modeler (2).
- This control method therefore constitutes an industrial automation (3) for more efficient production control.
- a first auxiliary variant characteristic of implementation of the method and control device according to the invention further consists in that it is electronically imposed that the defect coefficients of the productive subsystems Sj j are higher when the aggregated stresses have more important.
- inductive probabilistic processor (12) for the evaluation of stress transmissions from one floor to the upper floor, we take into account the fact that, in the In most cases, the high default coefficients appear precisely when the stress is high, causing a significant increase in the average level of stress transmitted to the upper floor and, consequently, in the value of the overall induced effect.
- the modeler (2) is imposed operating rules such that, for any threshold d ⁇ , he electronically fixes the probability laws of elementary faults Pr, ⁇ in such a way that P ⁇ , j (x z , T, r, W z ,, j , a, J [d Z ⁇ lj > d] increases with the value of the aggregate stress W Z ⁇ lJ .
- One of the advantages of the method and device according to this first auxiliary variant of the invention is that: one of the defects of conventional control systems is corrected, which by not respecting this additional method, leads to a significant under-evaluation of the number of cases where the industrial impact exceeds the authorized limit value M, one of the associated faults of these conventional systems is avoided which, in order to comply with industrial standards, tend to use greater safety margins and therefore reduce the flow of production.
- a second auxiliary variant characteristic of the method and control device according to the invention is! preferably implemented for a production of the diversified stress sequence type. That is to say a production of which the productive subsystems S ⁇ have characteristics of size and reliability which are independent.
- some of the productive subsystems S v may be small, both in terms of production sub-flows and in terms of own stress, reliable on their scale, i.e. their default coefficient for an aggregated stress of the same order of magnitude as their own stress will be low on average, but such that a significant aggregated stress can lead to an almost certain defect.
- other productive subsystems S tJ have the opposite property. That is to say that their sub-flow of production is high as well as their own stress. Their default coefficient has a high average but relatively stable even when the aggregate stress is high.
- the confidence coefficients ay are electronically fixed within the memory (14) of production parameters in the form of a quantity which has at least two independent components: - A first is electronically linked confidence coefficient component ay- to the size of the productive subsystem Sy to which it relates.
- a second confidence coefficient U component is linked electronically to reliability at. productive subsystem S y relative to its size.
- a third auxiliary variant characteristic of the method and control device according to the invention is applied specifically to a production whose factor environmental multivariate of production hazard X is subject, with a low probability, to very large and unpredictable movements.
- this variant (to electronically constitute said sampling of the state of production according to a pseudo-random method of “Monte-Carlo” type, the overall number of prints of which is Z), one proceeds electronically by a historical probabilistic combination and "Catastrophic".
- catastrophic situations of the different sub-factors of production hazard XJ, or even sub-families of catastrophic situations whose characteristics of mean and dispersion are defined: - either in absolute terms , or in relation to the characteristics of the distribution resulting from the analysis of the historical record included in the auxiliary memory (4).
- the weight Zp n (V) of said electronic samples is recorded electronically for each value V that the component I h can reach [sum of the numbers of electronic samples for which said component of impact I n (x z , T) (r) exceeds (up or down, depending on the type 1 or 2 of production to be checked) the value V multiplied by the associated weight m s or m c )].
- one determines the extreme multivalue, (r max ) or (r m , ⁇ ) according to the type of system, for which the multi-valued estimator NaR (p, T) (r) exactly equals the regulatory or breaking value M , and - the value of the action parameter (r) is adjusted to this level (possibly multiple) using a servo-type or servomotor type process.
- the biases observed between the real probability distribution of the hazard (X I , ..., X N ) and that of the values taken during the historical recording period are corrected characteristic data of the events. If certain events (with serious consequences and the probability of which cannot be overlooked) did not occur in the period in which this history was recorded, the production control automation (3) is nevertheless required to take them into account . If, by a compensation phenomenon, the simulation of a precise catastrophic event would not generate any significant industrial impact, thanks to the simulation of subfamilies of events, this accidental compensation is avoided and the real risk linked is highlighted to disaster.
- One of the major types of application of the invention is to control any harmful effect (such as pollution, etc.) of a productive device with stages, each stage of which is both capable of producing this harmful effect and of transmit to the next floor, but also has a power to control it at its level.
- any harmful effect such as pollution, etc.
- FIG. 3 diagrammatically represents the organization of a factory for implementing the method and the control device according to the invention therein, in order to optimize production, nevertheless checking that the internal noise at the factory is below a regulatory level. It should be noted that keeping noise or vibrations below a limit could be linked not to a regulatory constraint but to a breaking limit constraint linked to the intensity of the overall vibration of the platform on which the machines are mounted by example.
- FIG. 4 represents the different stages of implementation of the process and the particularities of the probabilistic automatism (3) for controlling the production of the plant and reducing noise.
- the industrial production center (1) is a factory containing noisy machine tools (S ⁇ J), whose operating intensity (r), i.e. their rhythm production, can be controlled.
- noise reduction For regulatory reasons related to the health of the operators of these machines, this brait must not exceed certain limits, except with a very low probability.
- a known system called “noise reduction” has been developed, operating using a network of microphones and loudspeakers placed in the engine room.
- the microphones record the noise at various strategic points in the room and transmit it to a programmed computer which, almost instantaneously, transmits a signal to loudspeakers distributed throughout the room.
- This signal called “noise reduction” is such that, if microphones and loudspeakers work correctly, it compensates, by a wave effect in phase opposition, for the noise of the machines. In this way, it is possible to cancel a very large proportion of this noise (up to more than 90%).
- noise reduction is, as a first approximation, a linear combination of the signals recorded by the microphones. It is the coefficients of this combination that the programmed calculator constantly registers by a "feedback" system. This part is known from the prior art.
- the present invention is applicable advantageous for minimizing this reduction or, if preferred, maximizing the operating intensity, while respecting the noise control standards, specifically in the case where the command to reduce (or increase) the intensity n does not have an immediate effect but acts with a delay T. It is then imperative to provide for the probability distribution of the amplitude of the noise resulting in the room during this delay in order to ensure that it will not exceed the regulatory levels that 'with a probability imposed by law.
- the multi-stage and multi-link system is made up of machines, microphones and speakers.
- the multivariate hazard factor (X) is the noise produced by the different machines as a sound wave. This noise is obviously random, even for a fixed and known operating intensity of the machines because, even if its amplitude is, in certain cases, purely a function of the operating intensity, the wave itself and, in particular, its phase, is random.
- time horizon Test the delay between the control of the intensity of the machines and the real variation of this intensity. It is during this delay that a random variation in noise is likely to exceed the standard. In this application, only the first stage, made up of machines, gives rise to sub-flows of production F ⁇ j . The production flow F is the result of these sub-flows.
- the industrial action parameter (r), here multivariate, is the intensity of operation of the machines. Each of its components corresponds to one of the machines.
- the industrial impact (I) (see ⁇ a-aaaa), also multivariate in this application, is the resulting brait in the room, after correction by noise reduction, as perceived by the operators. It has as many components as there are ears of operators in working condition in the room.
- the machines 'own stress w ⁇ j (see ⁇ b), which is also their • stras.-' aggregated W ⁇ j since it is the first stage, is the brait they produce.
- the transmission coefficient d j (see ⁇ ccc) is not random and remains equal to 1 because the machines do not control any noise by themselves.
- the .strass transmitted w ' 2d , k (see ⁇ bb) by the machine at the microphone S 2> * is equal to the noise created by the machine, that is to say its own stress, multiplied by a coefficient of sensitivity of the microphone to this brait q j ⁇ k (see ⁇ cc).
- the clean str. W .k of the micro S 2 ⁇ * is the result of other sources of brait than the machines perceived by the microphone.
- the aggregate stress W t (see ⁇ c) is the total actual noise perceived by the microphone. When the microphone "saturates” and, even worse, if it "clicks", the actual noise may differ from the signal actually recorded. The ratio between the recorded signal and the actual brait W.
- the strass transmitted w ' 3 ⁇ (see ⁇ bb) by the microphone S j to the speaker S 3 ⁇ / t is therefore equal to the product of the aggregate stress of the microphone W 2j by its transmission coefficient d j and by the noise reduction coefficient q 2j , k-
- the implementation of the method and of the invention in this particular application consists in producing an automatic control system (3) in accordance with FIG. 4, whose action loop (5) is a simulator of inductive probabilistic evaluation (11 ) random behavior:
- This process is characterized in that, in order to electronically generate the industrial impact (I), namely, the brait perceived by the operators, a probabilistic inductive processor ' (12) is set up according to the inductive method (11) for determining impact, i.e. containing the following steps:
- Monte-Carlo generator (8) generation by a random draw of the "Monte-Carlo" type, of the noise W ⁇ produced by the machines Si ,, according to the specifications of the user (9) and preferably using a historically adaptive behavior modeler (2), - Calculation, for each random draw, of the noise W j perceived by each microphone S 2j by applying the sensitivity coefficients q 2flJ ,
- the feedback loop (6) of this automatic control (3) aims to determine the maximum value (r m ⁇ ) of the operating intensity of the machines so that the parameter VaR does not exceed the prescribed value (M) specified similarly in the memory area (9) called operator specification.
- This loop is completed by a servomotor acting on the intensity control of the machines, and maintaining this calculated value (r max ) permanently.
- This staged procedure for calculating the final impact which takes into account on each stage and separately the signal exactly received by the subsystem and that which it emits, allows a better estimate of the probability of exceeding the sound threshold. authorized and, consequently, a decrease in safety margins and an increase in production flows for given safety standards.
- the implementation of the first variant of the method of the invention finds its justification in the fact that the risk of saturation and the importance thereof, both for microphones and for speakers, is all the more higher than the stress of these subsystems is important.
- the probability distribution Pr v of the transmission coefficient of the microphones and the loudspeakers is such that a greater perceived noise (microphones) or a signal to be transmitted (loudspeakers) results in a statistically more saturation level. high, as well as a more likely breakdown.
- the probability density Pr ⁇ over the interval [0,1] can be given a "bell" shape, the center of which moves to the right when the stress increases.
- saturation as well as breakdown, can on the one hand depend on the overall quality of the microphone or the speaker, but also on a "saturation threshold" specific to each device (microphone or speaker ) beyond which the saturation phenomenon becomes systematic, thus justifying the implementation of the second variant of the method of the invention.
- the confidence coefficient a tJ of the microphones and the loudspeakers has two components. A recommended form consists in taking one of these components equal to the saturation threshold, the other being a score attributed to the reliability of the device, which can be measured statistically.
- the third variant of the process of the invention is applicable when the machines are capable of emitting significant noise sporadically.
- the user specifies in the memory area (9) known as the operator specification, the frequency of these "explosive pulses" and a probability distribution of their intensity on the model of "catastrophe scenarios”.
- the probabilistic automaton (3) then generates a subsample of the values of the noise emitted consisting solely of explosive pulses.
- FIG. 5 schematically represents the organization of a clearing house (stock exchange) to implement the method and the automatic control system (3) according to the invention in order to maximize the volume of transactions (and therefore brokerage costs) collected) while maintaining the overall risk of financial loss (linked to the default of members) below a regulatory limit.
- FIG. 6 represents the different stages of implementation of the method and the particularities of the automatic control system (3) of the invention for the compensation chamber of FIG. 5.
- the technological organization of the probabilistic electronic automation (3) according to the invention to be implemented within a clearing house is described with reference to FIG. 6.
- the industrial production center (1) is in this application , a clearing house for financial markets, for example a stock exchange.
- stockbrokers An operator wishing to carry out a transaction must obligatorily entrust it to a stockbroker. When possible, the stockbroker puts operators who address him face to face and only places residual orders on the stock exchange (including those he places for his own account). The “clearing”, which summarizes all of the day's transactions, is carried out every evening. In the event that one of the operators proves to be defaulting, that is to say unable to complete his part of the transaction, the stockbroker is required to complete this part in his place. For this "performance guarantee", the stockbroker is remunerated by brokerage fees. In addition, the stockbroker generally asks each of his customers, that is to say the operators carrying out transactions through him, a security deposit, the amount of which depends on the transactions carried out.
- the volume of transactions, and therefore the amount of transaction fees collected by a stock exchange, and by the same token its economic efficiency, is directly linked in a decreasing way to the amount of security deposits that it imposes to its members (stockbrokers).
- the overall cost at the end of the day of the performance guarantee ie taking into account all the members
- M ⁇ , ... M H at most with frequencies regulated by law imposed.
- the excess capital which could lead to bankruptcy, should only occur with very little probability.
- the Stock Exchange In order to avoid that the defects of its members are too frequent, the Stock Exchange must not only ask them for sufficient security deposits but, moreover, must impose a minimum on them the amounts that they demand as a guarantee from their own customers. .
- the multi-stage and multi-link system is made up of operators (customers, members) as well as the Stock Exchange itself.
- the multi-stage structure of the overall system according to the invention appears in the following form:
- the productive sub-systems S tJ of the multi-stage and multi-link system are the operators (customers, members) as well as the Stock Exchange itself. This is a tree structure, if we consider the accounts of the same client with different members to be separate (even assuming a 100% correlation between account faults from the same client) . In fact, each client is linked to only one member and the top of the tree is made up of only one subsystem: the Stock Exchange.
- the multivariate hazard factor (X) is the set of price variations of the various assets listed on the stock market during the day. The impact of each of these assets on operators (customers, members or stock exchange) is equal to the product of the change in its price by the quantity of assets that operators have in their portfolios.
- the natural time horizon T is the day. However, it may be necessary to monitor market movements over several days if, for reasons of liquidity, the portfolio of a defaulting operator cannot be liquidated in a single day.
- Each transaction made for a client by a member gives rise to the payment of brokerage fees. All brokerage fees paid by a client S 1 (/ to a member S 2 ⁇ k represents the production sub-flow F 2jt k. Likewise, each transaction carried out by a member of the Stock Exchange gives rise to transaction costs The set of transaction fees paid by a member S 2j to the S 3 exchange represents the production sub-flow F ⁇ , d (there is no third index because there is only one subsystem in l (stage E 3 ). The production flow F is the sum of all the sub-flows F 3 ⁇ / , that is to say all the fees received by the Stock Exchange for the day. Each asset held in the portfolio gives a security deposit which, as a general rule, is proportional to the quantity of assets.
- the industrial action parameter (r) is the proportionality ratio between the quantity of assets and the associated security deposit. multivariate, because this ratio depends on the asset considered. The higher it is, the more the deposit required important, which has the consequence of reducing the risk of default, but also the volume of transactions, that is to say the production flow F and the sub-flows F, Jrk .
- the industrial impact (I) (see ⁇ a-aaaa) is, in this application, the total amount that the Stock Exchange must pay to the counterparties of its members in default under the "performance guarantee”. We can conceive of a second component to this industrial impact which would be the same amount, minus the sums recovered after the liquidation of members in default.
- the aggregate stress W tJ (see ⁇ b-bb) of the subsystems S, j is equal to the negative part of their financial result at the end of the day.
- the industrial impact (I) is identified with the aggregated stress WT, of the single subsystem of stage E 3 , that is to say the Stock Exchange.
- the amount of stress transmitted can be either all, or only a proportion, of the loss incurred by the client or the member. This proportion (equal to 1 if the default is total and to 0 if there is no default) is the default coefficient d XJ of the client or the member. This default coefficient (see ⁇ d-ddddd) is obviously an unknown.
- the confidence coefficient a tJ of the subsystem S v is called the operator's "rating". In existing systems of the prior art, this "rating" is a simple rating assigned to the operator.
- the present invention recommends a "rating" having at least two components. The first reflects the size or, in this case, the level of equity of the operator FP, j . The second reflects its reliability or, if you prefer, its probability of default for a given ratio between its aggregate stress W tJ (ie the loss incurred) and its equity FP tJ .
- the third variant of the process of the invention finds its justification in the
- the third variant of the invention recommends the simulation of a subfamily of catastrophic situations, certain samples of which will clearly show the real risk of the operator.
- FIG. 6 The implementation of the method and of the invention in this particular application linked to the dung beetle diagram is described in FIG. 6. It consists in carrying out a probabilistic automatic control (3) conforming to the general structure of that of FIG. 4, the action loop (5) is a simulator of inductive probabilistic evaluation (11) of random behavior: stock market prices, default of operators (customers and members), in order to generate as accurate a sampling as possible of the amount financial that will cost the Stock Exchange at the end of the day its performance guarantee obligation. This process is characterized in that, to generate the industrial impact electronically
- an inductive probabilistic processor (12) is set up according to the inductive method (11) of determining the impact, that is to say containing the following steps: - At l using the Monte-Carlo generator (8), generation by random draw of the "Monte-Carlo" type of X prices, of assets listed on the stock market, taking into account the catastrophe risks specified by the user in the memory area ( 9) called operator specification, W ⁇ tl
- the reaction loop (6) of this probabilistic automatic control (3) consists in determining the minimum values tr lmm , ..., r of the coefficients to be applied for the calculation of the security deposits so that the VaR parameter does not exceed the prescribed value (M) also specified in the memory area (9) called operator specification.
- This loop is completed by an automatic procedure for adjusting security deposits.
- This step-by-step procedure for calculating the final impact which takes into account the amount to be covered on each floor due to the failure of the subsystems of the previous stage for calculating the probability of failure of each subsystem, a better estimate of the probability of exceeding the authorized threshold and, consequently, a decrease in safety margins and an increase in production flows (financial activity of the stock market) for given safety standards.
- These security standards may cover in particular:
- the implementation, in the stock market diagram, of the first variant of the process of the invention finds its justification in the fact that the risk of default and the importance thereof, both for customers and for members, are higher the greater the stress of these subsystems.
- the probability distribution Pr rj of the default coefficient for customers and members is such that a financial loss (customers) or an overall amount to be covered - defaults + loss - (members) more important, results in a statistically higher default coefficient.
- the probability density Pr ⁇ could be made up of a probability l- /?
- the default of customers and members may depend on the one hand on the overall reliability of the operator, but also on a "default threshold" specific to each operator (customer or member) beyond which the default becomes almost inevitable, thus justifying the implementation of the second variant of the process of the invention.
- the confidence coefficient a tJ of customers and members has two components. A recommended form is to take one of these components equal to the amount of equity, the other being a rating attributed to the reliability of the operator, which can be provided by specialized rating agencies.
- the implementation of the third variant of the process is justified by the sudden price movements - upwards or downwards - which appear sporadically.
- the user specifies in the memory area (9) known as the operator specification, the frequency of these "catastrophic movements" and a probability distribution of their intensity on the model of "disaster scenarios”.
- the machine then generates a subsample of price values made up solely of disaster scenarios.
Abstract
Description
Claims
Priority Applications (6)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
US10/149,960 US7644005B1 (en) | 1999-04-21 | 2000-04-21 | Method and automatic control for regulating a multiple-stage industrial production controlling random chained stress, application to noise and value at risk control of a clearing house |
AU71936/00A AU7193600A (en) | 1999-04-21 | 2000-04-21 | Method and automatic control for regulating a multiple-stage industrial production controlling random chained stress, application to noise and value at risk control of a clearing house |
CA002406899A CA2406899C (fr) | 1999-04-21 | 2000-04-21 | Procede et automatisme de regulation d'une production industrielle etagee avec maitrise d'un stress enchaine aleatoire, application au controle du bruit et du risque var d'une chambre de compensation |
EP00922712A EP2062111B1 (fr) | 1999-04-21 | 2000-04-21 | PROCEDE ET AUTOMATISME DE REGULATION D'UNE PRODUCTION INDUSTRIELLE ETAGEE AVEC MAITRISE D'UN STRESS ENCHAINE ALEATOIRE, APPLICATION AU CONTROLE DU BRUIT ET DU RISQUE VaR D'UNE CHAMBRE DE COMPENSATION |
AT00922712T ATE463780T1 (de) | 1999-04-21 | 2000-04-21 | Verfahren und automatisierungsgerät zur regelung einer stufenförmigen industriellen fertigung mit umfassender kontrolle über zufällig miteinander verkettete belastung, anwendung zur steuerung des rauschens und das var-risiko eines kompensationsraums |
DE60044163T DE60044163D1 (de) | 1999-04-21 | 2000-04-21 | Verfahren und automatisierungsgerät zur regelung einer stufenförmigen industriellen fertigung mit umfassender kontrolle über zufällig miteinander verkettete belastung, anwendung zur steuerung des rauschens und das var-risiko eines kompensationsraums |
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
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FR9905074A FR2792746B1 (fr) | 1999-04-21 | 1999-04-21 | PROCEDE ET AUTOMATISME DE REGULATION D'UNE PRODUCTION INDUSTRIELLE ETAGEE AVEC MAITRISE D'UN STRESS ENCHAINE ALEATOIRE, APPLICATION AU CONTROLE DU BRUIT ET DU RISQUE VaR D'UNE CHAMBRE DE COMPENSATION |
FR99/05074 | 1999-04-21 |
Publications (2)
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WO2000065418A2 true WO2000065418A2 (fr) | 2000-11-02 |
WO2000065418A3 WO2000065418A3 (fr) | 2001-04-12 |
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US (1) | US7644005B1 (fr) |
EP (1) | EP2062111B1 (fr) |
AT (1) | ATE463780T1 (fr) |
AU (1) | AU7193600A (fr) |
CA (1) | CA2406899C (fr) |
DE (1) | DE60044163D1 (fr) |
FR (1) | FR2792746B1 (fr) |
WO (1) | WO2000065418A2 (fr) |
Cited By (2)
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EP1367524A2 (fr) * | 2002-05-31 | 2003-12-03 | Goldman, Sachs & Co. | Procédé et système de test sous contraintes du comportement des instruments financiers |
US10140422B2 (en) | 2013-03-15 | 2018-11-27 | Battelle Memorial Institute | Progression analytics system |
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US9729639B2 (en) | 2001-08-10 | 2017-08-08 | Rockwell Automation Technologies, Inc. | System and method for dynamic multi-objective optimization of machine selection, integration and utilization |
US8914300B2 (en) | 2001-08-10 | 2014-12-16 | Rockwell Automation Technologies, Inc. | System and method for dynamic multi-objective optimization of machine selection, integration and utilization |
US20090210081A1 (en) * | 2001-08-10 | 2009-08-20 | Rockwell Automation Technologies, Inc. | System and method for dynamic multi-objective optimization of machine selection, integration and utilization |
US20050075970A1 (en) * | 2003-10-06 | 2005-04-07 | Doyle Thomas James | Risk assessment system and method |
US8788247B2 (en) * | 2008-08-20 | 2014-07-22 | International Business Machines Corporation | System and method for analyzing effectiveness of distributing emergency supplies in the event of disasters |
US8972067B2 (en) | 2011-05-11 | 2015-03-03 | General Electric Company | System and method for optimizing plant operations |
US9031892B2 (en) | 2012-04-19 | 2015-05-12 | Invensys Systems, Inc. | Real time safety management system and method |
US10637240B2 (en) * | 2014-01-24 | 2020-04-28 | Fujitsu Limited | Energy curtailment event implementation based on uncertainty of demand flexibility |
EP3324254A1 (fr) * | 2016-11-17 | 2018-05-23 | Siemens Aktiengesellschaft | Dispositif et procédé de détermination des paramètres d'un dispositif de réglage |
AU2019364195A1 (en) * | 2018-10-26 | 2021-05-27 | Dow Global Technologies Llc | Deep reinforcement learning for production scheduling |
AU2021204532A1 (en) | 2020-03-17 | 2021-10-07 | Freeport-Mcmoran Inc. | Methods and systems for deploying equipment required to meet defined production targets |
CN111723093A (zh) * | 2020-06-17 | 2020-09-29 | 江苏海平面数据科技有限公司 | 基于数据划分的不确定间隔数据查询方法 |
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- 2000-04-21 AT AT00922712T patent/ATE463780T1/de not_active IP Right Cessation
- 2000-04-21 EP EP00922712A patent/EP2062111B1/fr not_active Expired - Lifetime
- 2000-04-21 CA CA002406899A patent/CA2406899C/fr not_active Expired - Fee Related
- 2000-04-21 DE DE60044163T patent/DE60044163D1/de not_active Expired - Lifetime
- 2000-04-21 US US10/149,960 patent/US7644005B1/en not_active Expired - Fee Related
- 2000-04-21 AU AU71936/00A patent/AU7193600A/en not_active Abandoned
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Also Published As
Publication number | Publication date |
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CA2406899C (fr) | 2009-11-24 |
ATE463780T1 (de) | 2010-04-15 |
AU7193600A (en) | 2000-11-10 |
US7644005B1 (en) | 2010-01-05 |
FR2792746A1 (fr) | 2000-10-27 |
EP2062111A2 (fr) | 2009-05-27 |
FR2792746B1 (fr) | 2003-10-17 |
EP2062111B1 (fr) | 2010-04-07 |
WO2000065418A3 (fr) | 2001-04-12 |
DE60044163D1 (de) | 2010-05-20 |
CA2406899A1 (fr) | 2000-11-02 |
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