China Sub-Regional June 2017 Consolidation
Overview
China's sub-regional model has a total of 63 preprocessor series. Although there are 652 preprocessor series in the IFs model, there are many that are not applicable to sub-regional models or do not significantly impact forecasts; only 355 preprocessor series are sought for sub-regionalization. Thus China's sub-regional model has nearly 18% coverage at this point. There are a 29 preprocessor series that have been identified that could be pulled into the model. If this data was to be pulled the the total coverage of the model would increase to nearly 26%.
Below is a table that shows the module coverage for the China sub-regional model. Population has the most coverage, but this is also the fewest number of preprocessor series. The economy module has the second highest coverage, which is good. Population and Economy have the greatest impact on the model's overall behavior and coverage in these modules is important. Health and education are areas of weakness for the China sub-regional model. In part the weakness is driven by the large number of series in those modules. There is more education data available that could be brought into the model, but some of the data requires historical age-sex cohorts to calculate rates with the data. Health has low coverage because there is not a lot of health data that is available for free and in English. It appears that much of China's health data is proprietary and not publicly available, but there may be alternative sources available if a researcher searched in Mandarin.
IFs Module | Preprocessor Series Pulled | Total Preprocessor Series | Module Coverage |
---|---|---|---|
Population | 7 | 8 | 87.5% |
Economy | 24 | 55 | 43.6% |
Health | 5 | 57 | 8.8% |
Education | 8 | 91 | 8.8% |
Agriculture | 11 | 36 | 30.6% |
Energy | 7 | 66 | 10.6% |
Infrastructure | 1 | 21 | 4.8% |
Environment | 0 | 9 | 0.0% |
Socio-Political |
0 | 12 | 0.0% |
Total | 63 | 355 | 17.7% |
Potential Series | 92 | 355 | 25.9% |
Population
China's Population
The provincial model's population for China was rolled up in IFs and compared to other population forecasts for China, as shown below. It is clear that the population forecast from the sum of the provinces (IFs_WB) is in line with other forecasting models. Nanjing University's forecasting model is the most off from the rest of the forecasts, where population growth is forecast to continue to rise.
It was difficult to find provincial forecasts on China, but there was one paper that was found in Mandarin that had provincial population forecasts for China's provinces. The paper from Nanjing University compared its forecasts to several other population forecasting models of China and this data was used to compare the IFs provincial model to. As was previously stated, Nanjing University's model has a steeper slope and forecasts population to continue to rise at the same rate, which all other forecasting models do not. This suggests that it might not be as good of a model as the others, but it gives some information about our forecasts.
Migration
Migration rates for China's provinces are not publicly available, nor are there forecasts of China's migration rates. This means that the model is without migration, which is problematic because intranational migration is a salient issue that is shaping provincial populations. For instance, Beijing's population pyramid shows a population that has been shaped by migration because of the large young working population relative to the number of children. There are also visible jumps up and down in population in provinces that are clearly attributed to migration.
To address the lack of migration data and appropriately capture the impact of migration within China, migration rates are estimated. First, provinces with net-in migration and net-out migration are identified by looking at the population data from 2000 through 2014. This span of years is when internal migration in China increased significantly and it is where migration rates are most visible in graphs of population. Below is a table that summarizes the migration trends that are visible in the provincial population and the following section shows graphs of population with history and forecasts for each province in China for comparison.
Net Inward Migration | Net Outward Migration | Flat Migration |
Beijing | Anhui | Chongqing |
Guangdong | Gansu | Fujian |
Hebei | Guizhou | Hunan |
Hubei | Guangxi | Jiangsu |
Jiangxi | Hainan | Liaoning |
Shanghai | Heilongjiang | Nei Mongol |
Tianjin | Henan | Ningxia |
Xinjiang | Jilin | Qinghai |
Shaanxi | Shandong | |
Sichuan | Shanxi | |
Yunnan | Tibet | |
Zhejiang |
Estimation Methods
Below is a province-by-province comparison of migration and population. First is population by province in the base case, without migration that is compared to Nanjing University's provincial population forecasts.
Second is the first method of migration stock estimation, this is the total number of migrants in millions. To estimate migrant stocks; historical crude birth rates, crude death rates, and population were used to calculate total births and deaths in millions starting in 1990. Births and deaths were then added to the previous year's population to generate an estimate of population without migration. For instance, population in 1990 for Anhui province is 54.7 million and births and deaths total to a net 0.84 million people in 1991. Then the population without migration in 1991 is estimated to be 55.54 million (54.7+0.84=55.54). These migration estimates are compared to a 5-year moving average of migrant stocks from a paper that estimated subnational migration in China from 1990 through 2005.
The third graph is a comparison of a second method of migration stock estimation with the first method and the paper's migrant stocks. The second estimation method is a five-year moving average of the first method's migrant stock.
Anhui
Population
Anhui's population takes a significant dip around 2008, which shows net-outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Beijing
Population
Beijing has a large jump up in population from 2005 through 2014, which shows net-inward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Chongqing
Population
The World Bank data was interpolated in the model which fills the population back to 1960 smoothly. In reality the municipality did not bifurcate from Sichuan until 1997 and its borders were redefined several times between 1997 and 2008. Thus Nanjing University's historical data's strange behavior makes sense, but the forecasts look too high.
Migrant Stock Estimate 1
The Chan paper's migrant stock estimates do not have data for Chongqing because the municipality did not come to be until 1997.
Migrant Stock Estimate 2
Gansu
Population
Gansu appears to have net-outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Guangdong
Population
Guangdong experienced rapid inward migration in the mid to late 2000s.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Guizhou
Population
Guizhou appears to have had significant net-outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Guangxi
Population
There is net-outward migration in Guangxi.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Fujian
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Hainan
Population
There appears to be net-outward migration in Hainan.
Migrant Stock Estimate 1
Migrant Stock 2
Hebei
Population
There appears to be net-inward migration into Hebei.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Heilongjiang
Population
There is net-outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Henan
Population
Henan province appears to have net-outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Hubei
Population
There are several other models that are compared here, the additional models were found in a paper that compared population models in China. IFs is in between all of the models, which is probably a good sign. There is a net-outward migration in the late 2000s.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Hunan
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Jiangsu
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Jiangxi
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Jilin
Population
There appears to be a small amount of outward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Liaoning
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Nei Mongol
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Ningxia
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Qinghai
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Shaanxi
Population
There is net-inward migration in Shaanxi.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Shandong
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Shanghai
Population
There is significant in-migration into Shanghai.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Shanxi
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Sichuan
Population
There is outward migration from Sichuan.
Migrant Stock 1
Migrant Stock 2
Tianjin
Population
There is significant inward migration into Tianjin
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Tibet
Population
Migrant Stock 1
Migrant Stock Estimate 2
Xinjiang
Population
There is net-inward migration.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Yunnan
Population
There is net-outward migration in Yunnan.
Migrant Stock Estimate 1
Migrant Stock Estimate 2
Zhejiang
Population
Migrant Stock Estimate 1
Migrant Stock Estimate 2
China's Crude Birth Rates
CBRs in the provincial model are quite close to the 186 model. There is a greater difference in the historical data than in the forecasts, but overall the two models are quite close.
China's Crude Death Rates
Like CBRs, CDRs are quite close in the two models. There is a greater difference towards the end of the forecasts after 2065.
China's Migration Rates
Migration rates that have been included in the model are historical and were found in a paper[1] that estimates sub-national migration in China. Chinese intranational migration has proven to be a difficult measure because there is a significant amount of illegal migration from rural areas to urban areas.
There is only historical data available. Therefore the migration rates do not impact the forecasts because the model does not endogenously calculate migration forecasts.
The two models appear to be different historically, but it should be noted that both models' migration rates are almost zero for all years. The difference between them is small in total, but the magnitude appears to be large.
China's Total Fertility Rates
There is only a single year of historical data for provincial TFR in China and unfortunately the data is from 2000, making this series outdated. For all provinces except Beijing, the 2000 historical data point is the same as the 2014 data point when the model initializes. Due to the outdated data being used for model initialization the provincial model's forecasts of TFR are slightly lower than the 186 model initially.
It is also important to note that provinces such as Beijing are outliers compared to the rest of the world due to the impact of the One Child Policy in China's urban areas. Unlike the rest of the world where TFR is forecast to decline to 1.9 and then remain at that level throughout the end of the time horizon, most provinces are forecast to have TFR increase to 1.9 and then remain at that rate through the end of the time horizon. Only Guizhou, Tibet, and Yunnan provinces have TFR above 1.9 historically that are forecast to decline to 1.9.
There are no known forecasts to compare the provincial forecasts for TFR with. The model's behavior looks good and without an available data source to update the historical data there is nothing that can be reasonably done to get the provincial model to match the 186 version.
China's Life Expectancy
Life expectancy in China's provincial model is in line with the 186 model historically and through the end of the time horizon in the forecasts. Male life expectancy is slightly lower in the provincial model than in the 186 model, but female life expectancy and total life expectancy are nearly identical in the two models.
Total Life Expectancy
Life Expectancy Female
Life Expectancy Male
Economy
China's GDP
Provincial GDP is significantly greater than the 186-model's GDP for most of the forecast years.
China's GDP per Capita
China's GDP per capita in the provincial model is significantly greater than the GDP. This is expected because the total population is quite close in both models, whereas, the GDP is greater.
Value Added
Value added in all sectors are relatively close in both models, but it is slightly lower in the provincial model overall. The disparity between the two model's GDP does not appear to be driven by value added.
Agriculture
The provincial model has higher value added in agriculture historically, but is forecast to have slightly lower value added in the future.
Energy
Value added in energy is forecast to be lower in the provincial model until around 2075 when the two models are forecast to be about the same.
Materials
Value added in materials is forecast to be lower in the provincial model by about a percentage point for all years.
Manufacturing
Manufacturing value added is relatively close in both models, with the provincial model being slightly greater.
Services
The two models are close historically and are forecast to be identical after 2035.
ICT
ICT forecasts are nearly identical.
MultiFactor Productivity
Multifactor productivity is significantly larger in the provincial model than in the 186-model. This is the likely culprit for what is driving the disparity between the two model's GDP forecasts.
Agriculture
The provincial model is slightly lower than the 186-model until around 2040. After 2040, the provincial model is greater than the 186-model by an increasing margin.
Energy
Multifactor productivity in energy is much greater in the provincial model.
Materials
Multifactor productivity in materials is much greater in the provincial model than in the 186-model.
Manufacturing
The provincial model has much greater multifactor productivity in manufacturing than the 186-model.
Services
Multifactor productivity is much greater in the provincial model.
ICT
Multifactor productivity is significantly greater in the provincial model.
GDS
Government spending is a key driver in the model and it directly impacts multifactor productivity, which appears to be off.
Military
Military spending is greater in the provincial model, why this is occurring is not clear because there is not any historical data for this series.
Education
The provincial model is initially greater than the 186-model and after 2055 the provincial model is lower. There is historical data in the provincial model for this series.
Health
The two models are initially close together, but over time the provincial model becomes greater than the 186-model by an increasing margin. There is historical data for this series.
Research and Development
There is more investment in research and development in the provincial model, but the total amount is very small in both models. This means that the marginal difference is small, but the magnitude of difference is significant. There is historical provincial data for this series.
Infrastructure
Infrastructure spending is close in the two models. There is not any historical provincial data for this series.
InfraOther
The provincial model has more InfraOther spending than the 186-model.
Other
Other spending is significantly greater in the provincial model.
- ↑ Kam Wing Chan, Forthcoming in; The Encyclopedia of Global Migration, edited by Immanuel Ness (Blackwell Publishing, 2017).