World DynamicsExamination of the structure of countervailing forces such as population growth, food production, capital investment, natural resources depletion, pollution, etc., at world level when exponential growth rate overburdens the environment - simulates world growth trends by means of a large-scale computer model and shows that a global equilibrium could be achieved if social policies and programmes were chosen taking into account the dynamic characteristics of world social systems. Flow charts. |
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Page 128
... Brn1 (Table 11.1). No immature loop stage loops of Henle was detected in Brn1 mutant mice until the last time point analyzed (postnatal day [P] 0) shortly before their death from renal dysfunction. This defines a requirement for Brn1 in ...
... Brn1 (Table 11.1). No immature loop stage loops of Henle was detected in Brn1 mutant mice until the last time point analyzed (postnatal day [P] 0) shortly before their death from renal dysfunction. This defines a requirement for Brn1 in ...
Page 269
... Brn1, and on the opposite strand. Deletion of Pantr1, therefore, may also delete portions of the proximal promoter of Brn1 and is likely to lead to a decrease in Brn1 transcription. Pantr2, however, is transcribed from a region ~10 kb ...
... Brn1, and on the opposite strand. Deletion of Pantr1, therefore, may also delete portions of the proximal promoter of Brn1 and is likely to lead to a decrease in Brn1 transcription. Pantr2, however, is transcribed from a region ~10 kb ...
Page 380
... Brn1 marks the loop of Henle and distal convoluted tubule during nephrogenesis. Brn1 immunostaining is first detected in a restricted cell population at the time of mesenchymal–epithelial transition in the early renal vesicle (RV; A, B) ...
... Brn1 marks the loop of Henle and distal convoluted tubule during nephrogenesis. Brn1 immunostaining is first detected in a restricted cell population at the time of mesenchymal–epithelial transition in the early renal vesicle (RV; A, B) ...
Contents
Introduction | 1 |
Structure of the World System | 17 |
A World Model Structure and Assumptions | 31 |
Copyright | |
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1970 conditions accumulation agricultural land assumed assumptions behavior billion birth rate normal birth-control program BRFM BRN1 CAPITAL UNITS CAPITAL UNITS/PERSON CAPITAL-INVESTMENT DISCARD capital-investment multiplier capital-investment ratio CAPITAL-INVESTMENT-IN-AGRICULTURE FRACTION cause Chapter CI=C CIAF CIGN1 CIMT Club of Rome coefficient computer model crowding ratio curve death rate normal decline DRFM dynamic ECIR effect effective-capital-investment ratio equations equilibrium exponential growth food production food ratio food supply FPMT FRACTION/YEAR in-agriculture fraction increase industrialization INTERPOLATION limit LOGICAL FUNCTION material standard mental models mode MULTIPLIER DIMENSIONLESS Natural resources Quality natural-resource Natural-resource-usage rate negative loop NR=N NREM NREMT POLAT pollution absorption pollution crisis POLLUTION UNITS pollution-absorption population and capital population density PRESENT ORIGINAL pressures QL-Q ratio CIR result rise Section sector shortage social systems SQUARE KILOMETERS standard of living structure system levels TABHL TABLE LOOK tion units per person UNITS/PERSON/YEAR UNITS/YEAR usage rate variable world model world population world system