Analysis of Spatial and Temporal Distribution Characteristics of Land Desertification Based on GIS and Remote Sensing Images

Due to the complex geographical situation in China, in this paper, the area of land desertification is 98.5% of the total land desertification area in China. Based on the measured data of GIS and remote sensing images, we will discuss the spatial and temporal distribution characteristics of land desertification in China by calculating standardized precipitation evapotranspiration index (SPEI) and normalized vegetation index and establishing the CA model. 'e results show the following. (1) 'e trend of desertification in China has decreased as a whole, and the percentage of nondesertification has increased from 36.91% in 1991 to 44.46% in 2020, an increase of 7.55%. Extremely severe desertification increased from 21.72% to 24.25%, an increase of 2.53%. (2) 'e drought situation in the study area gradually improved, and the change trend of SPEI decreased by 74%. (3) In recent ten years (2011–2020), the vegetation grew well gradually, and it was in the best state in 2018. 'e NDVI index value increased by 5.9% compared with the average value in this decade. (4) 'e model designed by us works very well, and the results of simulating and testing the 'ree Rivers Source region are very little different from the actual situation, which meets our research requirements.


Introduction
e Earth, on which human beings depend, is facing severe environmental challenges, such as air pollution, soil erosion, and garbage disposal, which threaten human survival and cause continuous and bad effects. Due to the vast territory and complex natural geography in China, the problem of land desertification is particularly prominent in some areas of China, and the desertified land accounts for 27.2% of the national area. It is precisely because the population affected by desertification in China is the largest, and people are deeply eroded by wind and sand, so the research methods and prevention means of land desertification in China are relatively mature. GIS and remote sensing images are commonly used technologies. By analyzing the spatial and temporal distribution characteristics of land desertification, we can choose a more optimized method to guide the desertification control. Remote sensing monitoring of desertification land in northern China in 2000 showed that desertification land developed rapidly [1], and desertification land in some dry farming areas and farming-pastoral ecotone areas was obviously reversed. Land cover, normalized difference vegetation index, cropland, woodland, and grassland maps were developed using remote sensing data and GIS monitoring [2]. In reference [3], GIS was used to evaluate land desertification, and wetness index, windy days, soil texture, and surface vegetation coverage were selected as evaluation factors of desertification sensitivity. Literature [4] found that desertification is serious from TM images of GIS, which is related to physical factors and differences in land use patterns. Literature [5] described the structural changes and development characteristics of desertification in Yanchi in detail through GIS and database. Literature [6] obtained the data of temporal and spatial change and differentiation model of desertification land around Qinghai and predicted the development trend of desertification in the next 20 years. Literature [7] described a GIS-based software tool for qualitative assessment of desertification risk. rough RS and GIS dynamic monitoring [8], it is found that land desertification is widespread in Longyangxia reservoir area of Qinghai Province. Literature [9] used Google Maps API, data cache, and other technologies to demonstrate the desertification situation in Lurgai area. Gad and Lotfy [10] produced ETM satellite imagery and geological and soil maps of the whole of Egypt, with a scale of 1 : 1000000. Literature [11] used GIS and ecosystem models to assist in assessing and mapping desertification. Literature [12] interpreted TM remote image of oasis lake area to analyze desertification evolution and simulated desertification dynamics by arc object module and cellular automata model. e spatial analysis function of ArcGIS 9.3 software [13] is used to evaluate the desertification index in southern Iraq, and the integrated remote sensing and GIS are used to evaluate the desertification environmentally sensitive areas. Literature [14] studied the dynamics of desertification and examined the accuracy of non-out-of-scope classification methods. According to RS and GIS information of Yijinhuoluo County in Muwu Sandy Land, Xu [15] established the estimation model of vegetation coverage rate and biomass. Desertification exists in some areas. is paper discusses the spatial and temporal distribution characteristics of land desertification in China by using the measured data of GIS and remote sensing images, calculating standardized precipitation evapotranspiration index (SPEI) and normalized vegetation index and establishing the CA model. rough the analysis of spatial and temporal distribution characteristics of land desertification, a more optimized method is selected to guide the desertification control.

Study the Relevant Theoretical Basis
Geographic Information System (GIS) uses GIS tools (or platforms) to display these data in the form of intuitive and effective maps and to display and describe its geographic analysis functions. GIS [16] is usually complementary to GPS technology [17] and satellite remote sensing technology [18]. It helps people in need to complete a series of work such as modeling, prediction, and detection. Now, GIS is no longer a distant "high-tech" product; it is quietly gradually into the public life. Everyone can easily use GIS service [19] to obtain geographical knowledge and data.
Remote sensing technology [20] is not a new detection technology in recent years. As early as 1960s, this technology has been produced and put into use in the exploration and monitoring of the Earth, which is used to obtain a large number of resources and environmental information. Because of the maturity of technology and the cheapness, convenience, and richness of obtaining data, it has been widely used in agriculture, forestry, ocean, geography, and other fields, which is closely related to people. Remote sensing technology uses photography to obtain images [21] to improve the accuracy of GIS and reduce the map update cycle [22]: (1) With the help of ternary wavelet transform [23], the formula is as follows: DA(x, y)〈DB(x, y), DA(x, y)〉DB(x, y), (2) Remote sensing images are corrected geometrically [24] to reduce the effects of distortion. e general flow of geometric correction is shown in Figure 1.
In Figure 1, because the remote sensing image will be geometrically deformed by the imaging lens, almost all kinds of remote sensing images need to be geometrically corrected to reduce the influence of distortion on data acquisition and generate more accurate maps or graphics that meet the requirements. e geometric registration [25] formula is as follows: 2.1. Introduction to ERADS Software. ERADS IMAGINE V9.2 developed by American ERADS Company is a powerful and easy-to-operate ERADS IMAGINE V9.2 product. is software product is technically mature and integrates the geographic information system (GIS) and remote sensing image processing. A great feature of this software is that it has a good and sufficient interface, which can communicate stably with other software (such as ARC/ INFO, Dbase, and Autocad), share functions and data, and greatly improve the usability of this product. Software versions are constantly updated and maintained, including the latest image processing algorithms, and adaptability is extremely strong. e functional system of the product is shown in Figure 2.

Cellular Automata (CA)
. Cellular automaton is a dynamic system. Represent a model with a formula as follows: Represent models in sets as follows: Formula (5) is a function that can explain the basic principle of cellular automata (CA). We use sets to express the cellular automata (CA) model. is expression is concise and clear, and the model is more intuitive. In particular, S is a finite set, which also represents cell state, N is the cell domain, variable t represents the time, and letter f represents the local transformation rule. e structure diagram of the model is shown in Figure 3.

Standardized Precipitation Evapotranspiration Index (SPEI).
Standardized precipitation evapotranspiration index (SPEI) can help us to analyze the dynamic process of land desertification at different levels, which is of great significance to the study of this paper. e formula for SPEI is as shown in equation (5) where w � ������� � −2 ln(P),  Scientific Programming 3 When P > 0.5, P is replaced by 1− P, and the value is reversed positively and negatively. F (x) is a function of water surplus and deficiency: Potential evapotranspiration is calculated by the following formula:

Ratio of Drought Stations (P j ).
e calculation formula of arid station frequency ratio is as follows:

Drought Intensity (S j ).
Drought intensity can evaluate the severity of drought. e larger the SPI value in the formula, the more serious the drought it represents. e specific calculation formula is shown as follows:

Normalized Vegetation Index (NDVI).
Using remote sensing image data and GIS, this study can obtain the spatial distribution map of vegetation growth in China's land desert areas, then calculate the normalized vegetation index (NDVI), and then analyze and map it. We can analyze the desertification and ecosystem in China according to the monitored vegetation coverage and growth, which is of great significance. e greater the NDVI, the denser the vegetation; the smaller the NDVI, the more sparse the vegetation. e calculation formula is shown as follows: China has a vast territory and a complex and changeable geographical situation. Due to the actual situation and technical reasons, this study cannot fully discuss the national land desertification situation. erefore, we mainly choose the northern region of China as the study area, and the land desertification in the northern region accounts for 98.5% of the total land desertification area in China, namely, Shaanxi, Ningxia, Hebei, Gansu, Qinghai, Inner Mongolia, Xinjiang, and Tibet. ese provinces have high research value in terms of geography and climate, and the rest provinces account for 1.5%, which are classified into one category because they are too scattered, so they only do brief discussion and research. e specific distribution map of 8 provinces of land desertification is shown in Figure 4. e data obtained in this study include land use map, basic statistical data, and second-hand data. e specific data processing specifications are shown in Table 1.

Analysis of Various Land Types.
We obtain the land type change data of desertification in northern China, and we can find that the land vegetation types are basically divided into desert, Gobi, bare land, sandy land, grassland, cultivated vegetation, meadow, alpine vegetation, coniferous forest, and broad-leaved forest. Desertification land accounts for the heaviest proportion in the figure. e details are shown in Figure 5. ere are basically five types of land use, as shown in Figure 6.

Classification and Classification System of Desertification.
In the study, the land desertification classification in the study area is convenient for researchers to make reasonable judgments and can quickly determine the degree and current situation of desertification in the region. We introduce Feng Yusun's evaluation system to classify desertification, as shown in Table 2. e desertification classification system is shown in Table 3.  Table 4. According to the above table, the general trend of land desertification in northern China is gradually decreasing, and the percentage of nondesertification has increased from 36.91% in 1991 to 44.46% in 2020, an increase of 7.55%. However, the extremely severe desertification increased from 21.72% to 24.25%, an increase of 2.53%. is shows that the ecological environment in desertification areas in China is gradually improving, but it is inevitable that some areas are not only not improving but also aggravating the trend of land desertification, which deserves the attention of local relevant departments, and more control and prevention should be given to land desertification. We need to assess the situation of land desertification from multiple angles and aspects, instead of measuring it with one or two unilateral factors.

Temporal and Spatial Variation
3.3.1. Regional Drought Dynamics. Drought is a serious meteorological disaster. Due to the greenhouse effect and the influence of various human activities, the economic loss  (1) e annual and seasonal changes of SPEI in the northern study area decreased as a whole, with a decrease area of 74% and a significant decrease area of 43%. In some areas, the increase area is 26%, and the significant increase area is 6%. As shown in Table 5, it is a statistical table of SPEI and drought grade change trend in northern study area. (2) Drought stations in different dry and wet areas from 1966 to 2020 are shown in Figure 7. We can find from the figure that the distribution of arid station frequency ratio in humid area is uneven, and the arid station frequency ratio is the least in some regional droughts. e ratio of drought stations and drought intensity in humid and semihumid areas showed an increasing trend. e ratio of arid stations and drought intensity in arid and semiarid areas showed a decreasing trend. (3) e tendency rate of SPI in different dry and wet areas from 1966 to 2020 is shown in Figure 8.
According to the analysis of SPI propensity rate in the line chart, we can obviously observe that SPI propensity rate increases in different dry and wet areas in different seasons. Figure 9 shows the average NDVI trend chart.

Changes in Desertification Vegetation Growth.
As shown in Figure 10, it is a change map of the vegetation index.
Vegetation in desertification areas has gradually grown well in recent ten years. In 2018, the state was the best, and the NDVI index value increased by 5.9% compared with the average value in this decade. e ecosystem of desert areas in northern China has gradually improved, and the trend of desertification has been gradually controlled.

Dynamic Simulation Analysis of Desertification in the Source Region of the ree Rivers.
Because of the vast land in northern China, the development status of each region is different, so it is difficult to carry out dynamic simulation and prediction analysis uniformly. Considering the money cost, time cost, and difficulty of data extraction, we choose Sanjiangyuan region, which is located in the south of Qinghai Province and the hinterland of Qinghai-Tibet Plateau, as a regional dynamic simulation and prediction analysis of land desertification. As shown in Figure 11, it is the geographical location map of the Sanjiangyuan region.

Data Preparation and Preprocessing.
To simulate the evolution of desertification, we need to collect various spatial data and statistical data, use ERADS software to preprocess the original data, extract important data from GIS and remote sensing images, and standardize the data after processing. is processing can effectively prevent the original data measured by us from being affected by interference factors such as human factors and equipment factors and ensure the accuracy of experimental results.
ere are two data standardization methods when preprocessing data.    6 Scientific Programming (1) Min-max standardization method is as follows: (2) Z-score standardization method is as follows: In this paper, the min-max standardization method is adopted, as shown in Table 6, which is partially standardized data. e CA model selected in this study is based on raster data. e realization of the CA model should first define the state and type of land, then monitor the desertification land in the source region of the ree Rivers, and comprehensively judge the influence degree of desertification by various indicators. We select the data in 2000 to run the model, compare the simulated desertification results in 2018 with the actual land desertification distribution in 2018, then constantly adjust and run the model, and finally select the more suitable model parameters for evolutionary simulation analysis.      Scientific Programming Taking the land desertification in the source region of the ree Rivers in 2000 as the initial state, the model is run. e accuracy is tested by Kappa, and the calculated result is 0.864, and the simulation result is ideal.
e goal is to unify the specifications, facilitate data processing, and avoid more troubles caused by the confusion of various data formats.
In equation (8), the ratio of drought stations can be used to evaluate the size and severity of drought range, M refers to the total number of weather stations in the study area in the north, J refers to different years, and MJ refers to the number of weather stations with drought in J year.
In equation (10), Band1 is the reflectivity in red band and Band2 is the reflectivity in near infrared band. e greater the calculated NDVI value, the greater the vegetation density. e smaller the NDVI value, the smaller the vegetation density. In particular, the NDVI value ranges from −1 to 1.
In equation (13), P 0 is the ratio of correct simulation, P c is the ratio of expected correct simulation in random case, and P p is the ratio of correct simulation in ideal classification case. Kappa > 0.75 indicates that the accuracy of the model is good. Figure 12, most of the Sanjiangyuan region is grassland. Desertification land accounts for 9% of the total area.

Simulation Test Comparisons.
In recent years, the ecosystem of Sanjiangyuan has been seriously damaged. Besides desertified land, nearly 70% of grassland is gradually desertified, and the annual desertification rate is maintained at 2.3%.
(1) Land Desertification in Sanjiangyuan Region. We compare the desertification situation in 2000 and 2018 tested by the model with the actual desertification situation in 2000 and 2018. It can be found that the results tested by our simulation system are not much different from the actual results. e average difference between the simulation test in 2000 and the actual monitoring results is 0.78, while the average difference between the simulation test and the actual monitoring results in 2018 is 1.31. e specific desertification statistics of available grassland are shown in Figure 13.     e model designed by us runs very well and has little difference with the actual situation, which meets our research requirements.

Conclusion
(1) Most of the study area is covered by desert. In the past 10 years, the general trend of desertification has gradually decreased, and the ecological environment has gradually improved. e percentage of nondesertification has increased from 36.91% in 1991 to 44.46% in 2020, an increase of 7.55%. Extremely severe desertification increased from 21.72% to 24.25%, an increase of 2.53%.
(2) e annual and seasonal variation trend of SPEI in the northern study area decreased as a whole, with a decrease area of 74%. e drought situation in the study area gradually improved. (3) In recent ten years (2011-2020), the vegetation in China's land desertification areas has gradually grown well, and it is in the best state in 2018. e NDVI index value has increased by 5.9% compared with the average value in the past ten years. Land desertification has been controlled in China. (4) e simulation test of land desertification in the source region of the ree Rivers has a good performance, and the difference between the test results and the actual results is basically very small, and the overall desertification trend in the source region of the ree Rivers is controlled.
e above data and methods in this paper are suitable for studying the spatial and temporal distribution characteristics of land desertification, but there are still some shortcomings and needs to be refined.

Data Availability
e experimental data used to support the findings of this study are available from the corresponding author upon request.

Conflicts of Interest
e author declares that there are no conflicts of interest regarding this work.