- #Assign equation number to scientific workplace 6 series#
- #Assign equation number to scientific workplace 6 free#
Exponential growth rate: the growth rate, r, between two points in time calculated from the equation r = ln(pn/p0)/n, where pn and p0 are the last and first observations in the period, n is the number of years in the period range, and ln is the natural logarithm operator.You should be aware that some results may be inappropriate (e.g., growth rates on current price series). Note: The operation will be performed on all selected series. Give a name to your custom function and click Add. To perform mathematical functions on the data over a specified time period, choose the type of operation from the dropdown menu, and then choose your time period. Select an appropriate weight variable (GNI, population, GDP, exports, imports, labor force or land area) from the Weight Indicator box, as shown above. No aggregate is shown if countries with missing data represent more than one third of the total population of your custom group. Weighted Mean 66POP: Aggregates are calculated as weighted averages of available data for each time period. Select an appropriate weight variable (GNI, population, GDP, exports, imports, labor force or land area) from the Weight Indicator box, as shown above.ġ1. No aggregate is shown if missing data account for more than one third of the observations in the series. Weighted Mean 66: Aggregates are calculated as weighted averages of available data for each time period.
Select an appropriate weight variable (GNI, population, GDP, exports, imports, labor force or land area) from the Weight Indicator box, as shown above.ġ0. Weighted Mean: Aggregates are calculated as weighted averages of available data for each time period.
#Assign equation number to scientific workplace 6 series#
Sums are not shown if more than one third of the observations in the series are missing.ĩ.
Sum 66: Aggregates are calculated as the sum of available data for each time period. Sum: Aggregates are calculated as the sum of available data for each time period.Ĩ. Min: Aggregates are set to the lowest available value for each time period.ħ. Values are not computed if more than a third of the observations in the series are missing.Ħ. Median 66: Aggregates are calculated as the median of available data for each time period. Median: Aggregates are calculated as the median of available data for each time period.ĥ. Values are not shown if more than one third of the observations in the series are missing.Ĥ. Mean 66: Aggregates are calculated as the average of available data for each time period. Mean: Aggregates are calculated as the average of available data for each time period.ģ. Max: Aggregates are set to the highest available value for each time period.Ģ. The sum of the oxidation numbers in a polyatomic ion is equal to the charge of the ion. For example, the sum of the oxidation numbers for SO 4 2- is -2.1.The sum of the oxidation numbers of all of the atoms in a neutral compound is 0.The oxidation number of a Group VIIA element in a compound is -1, except when that element is combined with one having a higher electronegativity. The oxidation number of Cl is -1 in HCl, but the oxidation number of Cl is +1 in HOCl.The oxidation number of a Group IIA element in a compound is +2.The oxidation number of a Group IA element in a compound is +1.The oxidation number of oxygen in compounds is usually -2. Exceptions include OF 2 because F is more electronegative than O, and BaO 2, due to the structure of the peroxide ion, which is 2.The usual oxidation number of hydrogen is +1. The oxidation number of hydrogen is -1 in compounds containing elements that are less electronegative than hydrogen, as in CaH 2.The oxidation number of a monatomic ion equals the charge of the ion. For example, the oxidation number of Na + is +1 the oxidation number of N 3- is -3.
#Assign equation number to scientific workplace 6 free#