Abstract: The present invention relates to an apparatus for displaying display information according to a driving environment and a method thereof. The apparatus for displaying display information according to the driving environment according to the present invention includes an input unit receiving driving environment information, a memory in which a program for controlling internal and external displays of a vehicle according to a driving environment is stored, and a processor executing the program, wherein the processor controls to select and project display information according to the driving environment information in an internal screen area and an external screen area according to preset partitioning.

Abstract: A method for controlling a vehicle interacting with a console display includes determining a position of the console display; determining an interaction state of the console display; and controlling an output state to be displayed on the console display based on the position information of the console display and an interaction state of the console display.

Abstract: This invention relates to a method for determining a map of expectation and/or of variance of height of liquid hydrocarbon in a geological model. The method allows analytical resolution of these maps while taking account of the uncertainties in the variables allowing this calculation such as the porosity or oil saturation of the rock and also the uncertainty in the presence of certain types of facies given by the apportionment cubes of architectural elements pAE(c) and proportion cubes for each facies, these proportions then having a triangular distribution defined by the following three values pA,AE,min(c), pA,AE,max(c) and pA,AE,mode(c). In particular, the method comprises the calculation of the sum of the plurality of architectural elements of pAE(c)·?(pA,AE,min(c)+pA,AE,max(c)+pA,AE,mode(c)) and the determining of a value of expectation of height of liquid hydrocarbon for said column as a function of the sum determined.

Abstract: The present invention relates to a method for determining at least one combined proportion cube. For each one of a plurality of facies, the determination involves receiving a reference proportion cube, said reference proportion cube having a first average proportion, and receiving an auxiliary proportion cube. Furthermore, for at least one of a plurality of facies, the determination comprises the modification of the auxiliary proportion cube, wherein the modified auxiliary proportion cube has a second average proportion, and the second average proportion is at a distance that is lower than a predetermined distance of the first average proportion and the combination of said reference proportion cube and said modified auxiliary proportion cube.

Abstract: This invention relates to a method for determining a map of expectation and/or of variance of height of liquid hydrocarbon in a geological model. The method allows analytical resolution of these maps while taking account of the uncertainties in the variables allowing this calculation such as the porosity or oil saturation of the rock and also the uncertainty in the presence of certain types of facies given by the apportionment cubes of architectural elements pAE(c) and proportion cubes for each facies, these proportions then having a triangular distribution defined by the following three values pA,AE,min(c), pA,AE,max(c) and pA,AE,mode(c). In particular, the method comprises the calculation of the sum of the plurality of architectural elements of pAE(c)·?(pA,AE,min(c)+pA,AE,max(c)+pA,AE,mode(c)) and the determining of a value of expectation of height of liquid hydrocarbon for said column as a function of the sum determined.

Abstract: The present invention relates to a method for determining at least one combined proportion cube. For each one of a plurality of facies, the determination involves receiving a reference proportion cube, said reference proportion cube having a first average proportion, and receiving an auxiliary proportion cube. Furthermore, for at least one of a plurality of facies, the determination comprises the modification of the auxiliary proportion cube, wherein the modified auxiliary proportion cube has a second average proportion, and the second average proportion is at a distance that is lower than a predetermined distance of the first average proportion and the combination of said reference proportion cube and said modified auxiliary proportion cube.

Abstract: Several sources of uncertainty need to be taken into account when assessing the static volume of hydrocarbons in a deposit. A base case is selected for each source of uncertainty. For each source of uncertainty, a probability distribution of the static volume is estimated when said source varies while the other sources comply with the base cases. A conversion table is constructed, of which each row has, for each source of uncertainty, a quantile value corresponding to a volume value according to the probability distribution estimated for this source and, furthermore, having a resultant value of the static volume calculated on the basis of the volume values associated with the quantile values of the row. A row of the conversion table which has a resultant value of the static volume of hydrocarbons that is equal or closest to the target value of the static volume is selected to adjust the sources of uncertainty in a geological model.

Abstract: Since the static volume of hydrocarbons in a deposit can be determined using a model built from a group of parameters, several sources of uncertainty are taken into consideration at least some of which are associated with respective parameters of the group. A base case is selected for each source of uncertainty. A probability distribution of the static volume of hydrocarbons is estimated when said source of uncertainty varies while the other sources comply with the base cases thereof. The Monte Carlo approach is used to draw a set of values of volumes from the distributions associated with each source value of volume VHCIP taking into account the impact of the different sources of uncertainties and estimating a distribution of the calculated values of volume VHCIP.