The housing market is heavily dependent on two main factors; supply and demand. Both play a major role in determining an equilibrium price for both sellers and buyers in the real estate market.
Residents, or the general population of individuals, place significant reliance on financial institutions to provide sources of capital i.e mortgages, to fund their purchases of homes. The rate of interest charged by these organisations in turn gives buyers (consumers) purchasing power, creating demand.
Supply is made up of the number of houses in the market, and consequently, of these, the number of houses which are up for sale. As the prices of houses for sale increases, the demand for purchase of these properties decreases. Conversely, the lower price, the higher the demand. Once the market reaches an equilibrium point, to which buyers and sellers form an agreement, houses are sold accordingly. An underlying factor to consider is the cost of construction, which impacts producers, or suppliers in this instance, and thus the number of homes for sale, and the expected profit sellers hope to achieve.
The simulated graph highlights the common scenario within the housing market, to which we see that as price increases, the total number for houses for sale decreases, generating an opposite slope to the price. As the price for houses increases, the demand for the houses decreases and vice versa. The equilibrium is evident at time 14 whereby the price of houses and the number of houses for sale overlaps which in turn creates a market to which both buyers and sellers are happy.
A model of the ebb and flow of agricultural societies, like China's history. From Khalil Saeed and Oleg Pavlov's WPI 2006 paper See also the Generic structure Insight Map
WIP Overview model structures of Khalid Saeed's 2014 WPI paper Jay
Forrester’s Disruptive Models of Economic Behavior See also General SD and Macroeconomics CLDs IM-168865
Added several versions of the model. Added a flow to make C increase. Added a factor to be able to change the value 0.5. Older version cloned at IM-46280
Like previous models, this model shows the operation of a simple economy, the influence of changes in the consumption rate, and the effect of government intervention. In addition, this model shows changes in the hypothetical general price level. It gives an idea of changes in price trends based on changes in the quantity of money. NOTE: No general price level exists. Prices provide information for the exchange of individual economic goods.
The model is built to demonstrates how Burnie Tasmania can deal with a new COVID-19 outbreaks, taking government policies and economic effects into account.
The susceptible people are the local Burnie residents. If residents were infected, they would either recovered or dead. However, even they do recover, there is a chance that they will get infected again if immunity loss occurs.
From the simulation result we can see that with the implementation of local government policies including travel ban and social distancing, the number of infected people will decrease. The number of recovered people will increase in the first 5 weeks but then experience a decrease.
In addition, with the implementation of local government policy, the economic environment in Burnie will be relatively stable when the number of COVID-19 cases is stable.
Wealth can be seen as the factories,
infrastructure, goods and services the population of a nation dispose of. According
to Tim Garrett, a scientist who looks at
the economy from the perspective of physics, it is existing wealth that generates
economic activity and growth. This growth demands the use of energy as no
activity can take place without its use. He also points out that the use of this
energy unavoidably leads to concentrations of CO2 in the
atmosphere. All this, Tim Garrett says, follows from the second law of thermodynamics.
If wealth decreases then so does economic activity and growth. The CLD tries to illustrate how wealth,
ironically, now generates the conditions and feedback loops that may cause it to decline. The consequences are inevitably economic stagnation (or secular recession?).
You can
read about the connection Tim Garrett makes between 'Wealth, Economic Growth,
Energy and CO2 Emissions' simply by
Googling 'Tim Garrett and Economy'.
Eastern oyster growth model calibrated for Long Island Sound Developed and implemented by Joao G. Ferreira and Camille Saurel; growth data from Eva Galimany, Gary Wickfors, and Julie Rose; driver data from Julie Rose and Suzanne Bricker; Culture practice from the REServ team and Tessa Getchis. This model is a workbench for combining ecological and economic components for REServ. Economic component added by Trina Wellman.
This is a one box model for an idealized farm with one million oysters seeded (one hectare @ a stocking density of 100 oysters per square meter)
1. Run WinShell individual growth model for one year with Long Island Sound growth drivers;
2. Determine the scope for growth (in dry tissue weight per day) for oysters centered on the five weight classes)
3. Apply a classic population dynamics equation:
dn(s,t)/dt = -d[n(s,t)g(s,t)]/ds - u(s)n(s,t)
s: Weight (g) t: Time n: Number of individuals of weight s g: Scope for growth (g day-1) u: Mortality rate (day-1)
4. Set mortality at 30% per year, slider allows scenarios from 30% to 80% per year
5. Determine harvestable biomass, i.e. weight class 5, 40-50 g (roughly three inches length)
This model shows the operation of a simple economy. It demonstrates the effect of changes in the fractional rate of consumption (or the converse the fractional rate of saving.)
In summary, lower rates of consumption (based on production) result in higher rates of production and consumption in the long-run.
A simple implementation of a Dynamic ISLM model as proposed by Blanchard (1981), and taken from An introduction to economic Dynamics - Shone (1997) - chapter 5. This model might serve as a framework to evaluate economic policies over GDP growth.
This model is an attempt to simulate what is commonly
referred to as the “pesticide treadmill” in agriculture and how it played out
in the cotton industry in Central America after the Second World War until
around the 1990s.
The cotton industry expanded dramatically in Central America
after WW2, increasing from 20,000 hectares to 463,000 in the late 1970s. This
expansion was accompanied by a huge increase in industrial pesticide
application which would eventually become the downfall of the industry.
The primary pest for cotton production, bol weevil, became increasingly
resistant to chemical pesticides as they were applied each year. The
application of pesticides also caused new pests to appear, such as leafworms,
cotton aphids and whitefly, which in turn further fuelled increased application
of pesticides.
The treadmill resulted in massive increases in pesticide
applications: in the early years they were only applied a few times per season,
but this application rose to up to 40 applications per season by the 1970s;
accounting for over 50% of the costs of production in some regions.
The skyrocketing costs associated with increasing pesticide
use were one of the key factors that led to the dramatic decline of the cotton
industry in Central America: decreasing from its peak in the 1970s to less than
100,000 hectares in the 1990s. “In its wake, economic ruin and environmental
devastation were left” as once thriving towns became ghost towns, and once
fertile soils were wasted, eroded and abandoned (Lappe, 1998).
Sources: Douglas L. Murray (1994), Cultivating Crisis: The Human Cost of Pesticides in Latin America, pp35-41;
Francis Moore Lappe et al (1998), World
Hunger: 12 Myths, 2nd Edition, pp54-55.
Capitalism is in crisis and climate
change disruption is now beginning to hit the bottom line. Insurance companies
know this well. According to a report by the Bank of England, insured losses
have risen from $10 000 million in 1985 to $50 000 million in 2015. Climate change
cannot be reversed, and extreme weather events
will undoubtedly get worse in the future strengthening the disruptive effects
shown in the CLD. Another dynamic is that
companies will continue to automate and, as The Economic Policy Institute has shown,
fail to reflect productivity gains in workers' salaries. The result, stagnating
salaries is disastrous for demand, given that capitalism needs endlessly rising demand
and consumption. A further serious problem is that as climate change gets worse
there will be increasing demands for companies to assume their responsibility and
bear the costs of negative externalities. The CLD shows these factors which are likely
to lead to the collapse of the system: when capitalism can no longer generate 'capital'
it has stopped to serves any useful purpose.
The World3 model is a detailed simulation of human population growth from 1900 into the future. It includes many environmental and demographic factors.
THIS MODEL BY GUY LAKEMAN, FROM METRICS OBTAINED USING A MORE COMPREHENSIVE VENSIM SOFTWARE MODEL, SHOWS CURRENT CONDITIONS CREATED BY THE LATEST WEATHER EXTREMES AND LOSS OF ARABLE LAND BY THE ALBEDO EFECT MELTING THE POLAR CAPS TOGETHER WITH NORTHERN JETSTREAM SHIFT NORTHWARDS, AND A NECESSITY TO ACT BEFORE THERE IS HUGE SUFFERING.
BY SETTING THE NEW ECOLOGICAL POLICIES TO 2015 WE CAN SEE THAT SOME POPULATIONS CAN BE SAVED BUT CITIES WILL SUFFER MOST.
CURRENT MARKET SATURATION PLATEAU OF SOLID PRODUCTS AND BEHAVIORAL SINK FACTORS ARE ALSO ADDED
Use the sliders to experiment with the initial amount of non-renewable resources to see how these affect the simulation. Does increasing the amount of non-renewable resources (which could occur through the development of better exploration technologies) improve our future? Also, experiment with the start date of a low birth-rate, environmentally focused policy.
