Evaluation of green innovation efficiency in catering industry based on data envelopment analysis

With the development of the economy, a series of environmental problems have emerged, and the integration of green development ideas on the basis of innovation is an important engine and key choice for green transformation and development [1]. Green innovation intuitively embodies the coordination and unity of the two development concepts of green and innovation [2], and has become a hot topic. It opens up a new road for the traditional way of innovation. Promoting green technological innovation can accelerate the green, intelligent and renewable recycling process of the production process, and continue to initiate the green transformation of all kinds of production organizations in terms of development strategy, product service and organizational system, and thus promote the construction of green, efficient and low-carbon production system [3-5].

In today’s society, environmental awareness is increasing, the green development of products, services, values, culture and so on has become an important development direction of various industries [6], and the catering industry is no exception. Realizing green development not only helps to protect the environment and save resources, but also enhances the image and competitiveness of catering enterprises, attracts more consumers and realizes sustainable development [7-9]. Catering green innovation has also become a hot topic in the development of the current catering industry, which is not only related to environmental protection and sustainable development, but also reveals the enterprise’s commitment to social responsibility and the pursuit of innovation and development [10-11]. It is an all-round, multi-level project, in the integration of environmental protection concepts, resource management green and innovation, publicity and promotion strategies, policies and regulations to follow, etc. need to be carefully planned and continuous efforts of enterprises, in order to realize the transformation of sustainable food and beverage to do the pavement [12-14]. Only through continuous innovation and unremitting pursuit, can we realize the benign development of green catering and make positive contributions to the sustainable development of the industry. Meanwhile, with the in-depth implementation of green development strategy and scientific and technological innovation, the pace towards modernization has been accelerated, but due to the differences in the original structure of the industry, innovation resources and policies, there are certain differences in the efficiency of green innovation within and between regions [15-17]. In such a background, the efficiency evaluation of green innovation in catering is particularly important, with the intention that this evaluation can provide a reference basis for improving the efficiency of green innovation in catering industry.

Evaluating green innovation efficiency is an essential process for the development of the industry. Literature [18] measured green innovation efficiency using a directed distance function model in the context of relaxation measurement, revealing the impact and interrelationships of environmental regulations on the efficiency of green innovation, and providing references for the formulation of regulations. And literature [19] assessed the efficiency of industrial green innovation and marketing strategies using fuzzy hierarchical analysis and fuzzy weighted sum product evaluation, revealing that environmentally friendly packaging, product labeling, and partnerships are the best designs for green innovation and marketing strategies. In addition, literature [20] designed a non-radial directional distance function-data envelopment analysis model to evaluate green innovation efficiency. Literature [21] used a data envelopment analysis-Malmquist index to measure the inputs and outputs of regional green innovation efficiency, showing that there are differences in efficiency between regions, but they are all in an upward state. Similarly, literature [22] evaluated the green technology innovation efficiency of emerging industries using Malmquist index-Data Envelopment Analysis, showing that the trend of its change is gradually increasing, thanks to technological progress and technical efficiency. This reference to data envelopment analysis is used as an analytical tool to assess the relative efficiency of multiple decision-making units, and the efficiency of various production, service, and decision-making processes can be effectively evaluated [23]. It uses the inputs and outputs of decision-making units, such as a firm, to determine the maximum outputs and minimum inputs of the firm in a given resource context. According to existing studies, data envelopment analysis is a commonly used tool to assess the efficiency of green innovation. However, there is no evaluation study on the green innovation efficiency of the catering industry, which, as an essential industry in social production, has an irreplaceable position in the green and innovative development of society.

The SBM-DEA model and convergence theories are used to evaluate the green innovation efficiency of China’s catering industry in multiple dimensions and explore the convergence characteristics of green innovation efficiency. On the basis of data envelopment analysis (DEA), this paper combines the SBM model and Malmquist-Luenberger productivity index, constructs the SBM-DEA model based on non-expected output, and evaluates and analyzes the static efficiency value and the dynamic efficiency value in terms of two dimensions, namely, time and space, respectively. Then, the convergence of green innovation efficiency in China’s catering industry was analyzed in terms of σ-convergence and absolute β-convergence, respectively.

2

Evaluation of Green Innovation Efficiency in Catering Industry Based on SBM-DEA Modeling

This chapter firstly constructs the evaluation index system of green innovation efficiency in the catering industry, and then proposes the SBM-DEA model based on non-expected output and introduces the Malmquist-Luenberger productivity index to realize the dynamic evaluation of green innovation efficiency in the catering industry.

2.1

Construction of the indicator system

The selection of green innovation efficiency evaluation indexes directly determines the accuracy and comprehensiveness of the results, this paper sets up an evaluation index system from multiple perspectives on the basis of existing research and in combination with the research object and research objectives of this paper. According to the definition of green innovation efficiency, comprehensively considering the aspects of science and technology, resources, environment, etc., the indicators are selected from the three aspects of inputs, desired outputs and non-desired outputs.

1)

Input indicators

Human input and capital input are the most commonly used input indicators for evaluating innovation efficiency. On this basis, this paper incorporates environmental protection elements into the indicator system when estimating the green innovation efficiency of the catering industry. In terms of capital input, according to the value chain of innovation behavior of catering enterprises, this paper chooses the common indicator of internal expenditure of R&D funds in R&D link, and chooses the green technology and environmental protection material R&D funds in service link to represent the capital input of scientific and technological services. In terms of manpower input, the international common indicator for the full-time equivalent of R&D personnel is selected. In terms of environmental protection input, this paper selects the procurement volume of environmental protection equipment and green raw materials to represent the environmental protection input of green innovation.

2)

Desired output indicators

The desired output of green innovation is reflected in two aspects: one is the technical value and the other is the economic value. Technical value represents the independent innovation ability of catering enterprises, which is an important embodiment of their sustainable development. The economic value is the starting point of innovation input for catering enterprises, and is also one of the characteristics of the innovation behavior of the enterprise organization form. In this paper, we choose the number of green dishes launched to represent the technical value of the catering enterprise, and choose the income from the sales of new dishes to represent the economic value, and construct the green innovation desired output vector.

3)

Non-desired output indicators

When measuring the efficiency of green innovation, environmental pollution and resource waste should also be considered, so this paper incorporates the indicators that can reflect the environmental pollution and resource waste into the output indicator system, i.e., non-expected output indicators. In this paper, the total amount of wastewater discharged from the catering industry, the total amount of oil smoke discharged from the catering industry, and the amount of waste generated from the catering industry (including food waste and disposable dishes and chopsticks, etc.) are chosen as non-desired outputs reflecting the situation of environmental pollution.

2.2

Research methodology

2.2.1

Base DEA model

Data Envelopment Analysis (DEA) belongs to one of the non-parametric technical efficiency analysis methods [24]. The CCR model based on constant returns to scale and the BCC model based on variable returns to scale are two of the most widely used and fundamental models of DEA theory [25].

The CCR model assumes that there are n DMUs, denoted DMU_j(j = 1,2,⋯,n). Each DMU has m inputs, denoted x_i(i = 1,2,⋯,m), and s outputs, denoted y_r(r = 1,2,⋯,s), with x_n denoting the amount of input factors for DMU_i the ith item, and assuming that v_i is the weight of the inputs for the ith item, and that u_i is the weight of the outputs for the r th item, the CCR model is expressed as follows: (1) $\begin{array}{l} \min θ \\ s . t . {\begin{array}{l} \sum_{j = 1}^{n} x_{i j} λ_{j} + s_{j}^{-} = θ x_{i k}, i = 1, 2, \dots, m \\ \sum_{j = 1}^{n} y_{r j} λ_{j} - s_{r}^{+} = y_{r k}, r = 1, 2, \dots, s \\ λ \geq 0 \\ s_{j}^{-} \geq 0 \\ s_{j}^{+} \geq 0 \\ j = 1, 2, \dots n \end{array} \end{array}$

Where λ is a linear combination of coefficients of DMUs, the optimal solution of the model θ^* is the value of efficiency and the value of efficiency is in the range of (0, 1], and $s_{i}^{-}, s_{i}^{+}$ denotes the input and output slack variables respectively. The above model is a measure of inefficiency in terms of the extent to which each input can be scaled down in equal proportions under certain conditions of output, hence it is known as an input-oriented CCR model.

The BBC model adds constraint $\sum^{n} λ_{i} = 1 (λ \geq 0)$ to the CCR model, which serves to make the production scale of the projection point at the same level as the production scale of the evaluated DMU, then the input-oriented BBC model is as follows: (2) $\begin{matrix} \min θ \\ s . t . {\begin{matrix} \sum_{j = 1}^{n} x_{i j} λ_{j} + s_{j}^{-} = θ x_{i k}, i = 1, 2, \dots, m \\ \sum_{j = 1}^{n} y_{r j} λ_{j} - s_{r}^{+} = y_{r k}, r = 1, 2, \dots, s \\ \sum_{j = 1}^{n} λ_{j} = 1 \\ λ \geq 0, s_{j}^{-} \geq 0 s_{j}^{+} \geq 0, j = 1, 2, \dots n \end{matrix} \end{matrix}$

The character representation of the BBC model is consistent with the CCR model.

2.2.2

SBM-DEA model based on undesired outputs

Most of the basic DEA models do not take into account the input and output slackness problem when measuring efficiency, which leads to a certain bias in their measurement results. In order to deal with this problem, this paper adopts the SBM-DEA model, which introduces slack variables of inputs and outputs in the objective function, which not only solves the problem of input slackness, but also deals with the problem of evaluating the efficiency under non-desired outputs, which is more in line with the nature of green innovation efficiency. In addition, the SBM-DEA model is also a non-radial and non-angle efficiency evaluation model, which can effectively prevent the bias of the efficiency measurement results due to the difference of radial and angle choices, and ensure the accuracy of the measurement results [26]. The SBM-DEA model is described as follows:

Suppose there are n DMUs, each of which contains three vectors, where the input vector is denoted as x ∈ R^m, the desired output vector is denoted as y^g ∈ R^s₁, and the undesired output vector is denoted as y^b ∈ R^s₂. Define matrix X,Y^g,Y^b as follows: [X] = ⌈x₁,…,x_n⌉^T ∈ R^m×n, $⌈ Y^{g} ⌉ = {⌈ y_{1}^{g}, \dots, y_{n}^{g} ⌉}^{T} \in R^{s_{1} \times n}$ , $⌈ Y^{b} ⌉ = {⌈ y_{1}^{b}, \dots, y_{n}^{b} ⌉}^{T} \in R^{s_{2} \times n}, X > 0, Y^{k} > 0, Y^{b} > 0$ . The production possibility set P can then be expressed as: (3) $\begin{array}{l} \bar{P} = P \ (x_{0}, y_{0}) \\ = {(\bar{X}, {\bar{y}}^{g}, {\bar{y}}^{b}) | \bar{X} \geq \sum_{j = 1, \neq 0}^{n} λ_{j} X_{j}, {\bar{y}}^{g} \leq \sum_{j = 1, \neq 0}^{n} λ_{j} y_{j}^{g}, {\bar{y}}^{b} \geq \sum_{j = 1, \neq 0}^{n} λ_{j} y_{j}^{b}, λ \geq 0} \end{array}$

Then the SBM-DEA model is represented by equation (4): (4) $\begin{array}{l} P^{*} = \min \frac{1 - \frac{1}{m} \sum_{i = 1}^{m} \frac{s_{i}^{-}}{x_{i 0}}}{1 + \frac{1}{s_{1} + s_{2}} [\sum_{i = 1}^{s_{1}} \frac{s_{r}^{g}}{y_{r 0}^{g}} + \sum_{i = 1}^{s_{2}} \frac{s_{r}^{b}}{y_{r 0}^{b}}]} \\ s . t {\begin{array}{l} x_{0} = X λ + s^{-} \\ y_{0}^{g} = Y^{g} λ - s^{g} \\ y_{0}^{b} = Y^{b} λ + s^{b} \\ s^{-} \geq 0, s^{g} \geq 0, s^{b} \geq 0, λ \geq 0 \end{array} \end{array}$

In the above equation, s is the relaxation of input and output, and λ is the weight vector. The objective function P^* is a decreasing function that decreases with s^*,s^g,s^b, and 0 ≤ P^* ≤ 1. For a DMU, when P^* = 1 and s^*,s^g,s^b are both equal to 0, the efficiency is valid. If P^* < 1 or s⁻,s^g,s^b is not equal to 0, it means that the DMU is inefficient and has some room for improvement.

2.2.3

Malmquist-Luenberger productivity index

The SBM-DEA model based on non-expected output proposed in the previous paper has obvious advantages in the static measurement of green innovation efficiency, but has some limitations in the dynamic evolution of green innovation efficiency. Therefore, in order to effectively analyze the dynamic evolution of green innovation efficiency in the catering industry, this paper introduces the Malmquist-Luenberger productivity index [27]. The Malmquist-Luenberger index is able to simultaneously incorporate both desired and non-desired outputs into the index system, and it can measure the green innovation efficiency in the presence of non-desired outputs, taking into consideration the The Malmquist-Luenberger index can simultaneously incorporate desired output and undesired output into the index system, can measure the green innovation efficiency in the presence of undesired output, takes into account the increase of desired output and the decrease of desired output, and has the good properties possessed by the Malmquist index, which is widely used in the study of the dynamic change of the production dynamic efficiency.

First assume that there are n DMUs, each of which contains three vectors, the input vector denoted x ∈ R^m, the desired output vector denoted y ∈ R^s₁, and the non-desired output vector $z \in R_{2}^{s}$ . The production possibility set P is denoted P(x) = {(y,b):x can produce(y,b)},x ∈ R^m, and P(x) satisfies the following requirements: closed set and convex set. Inputs and desired outputs can be adjusted. Joint weak disposability. Zero unionizability. Joint weak disposability shows that input costs are required to reduce non-desired outputs, and zero-integrability shows that with desired outputs there must be non-desired outputs. Then the DEA method is used to describe P(x), and then the directional distance function is used to solve for the optimal solution of the set, the directional distance function is: (5) ${\vec{D}}_{0} (x, y, b; g_{y}, g_{b}) = \max {β : (y + β g_{y}, b - β g_{b}) \in P (x)}$

where g = (g_y, g_b) is a directional vector indicating that firms face completely different attitudes towards desired and non-desired outputs in terms of utility and preferences. According to the related literature, the Malmquist-Luenberger model can be expressed as: (6) $M L_{t}^{t + 1} = {[\frac{1 + {\vec{D}}_{0}^{t} (x^{t}, y^{t}, b^{t}; y^{t}, - b^{t})}{1 + {\vec{D}}_{0}^{t} (x^{t + 1}, y^{t + 1}, b^{t + 1}; y^{t + 1}, - b^{t + 1})} \times \frac{1 + {\vec{D}}_{0}^{t + 1} (x^{t}, y^{t}, b^{t}; y^{t}, - b^{t})}{1 + {\vec{D}}_{0}^{t + 1} (x^{t + 1}, y^{t + 1}, b^{t + 1}; y^{t + 1}, - b^{t + 1})}]}^{1 / 2}$

The ML index is equal to the product of the green innovation technology efficiency change index (MLEC) and the green innovation technology change index (MLTC), expressed respectively: (7) $M L E C_{t}^{t + 1} = \frac{1 + {\vec{D}}_{0}^{t} (x^{t}, y^{t}, b^{t}; y^{t}, - b^{t})}{1 + {\vec{D}}_{0}^{t + 1} (x^{t + 1}, y^{t + 1}, b^{t + 1}; y^{t + 1}, - b^{t + 1})}$ (8) $M L T C_{i}^{t + 1} = {[\frac{1 + {\bar{D}}_{0}^{t + 1} (x^{t}, y^{t}, b^{t}; y^{t}, - b^{t})}{1 + {\bar{D}}_{0}^{t} (x^{t}, y^{t}, b^{t}; y^{t}, - b^{t})} \times \frac{1 + {\bar{D}}_{0}^{t + 1} (x^{t + 1}, y^{t + 1}, b^{t + 1}; y^{t + 1}, - b^{t + 1})}{1 + {\bar{D}}_{0}^{t + 1} (x^{t + 1}, y^{t + 1}, b^{t + 1}; y^{t + 1}, - b^{t + 1})}]}^{1 / 2}$

Where $M L_{i}^{t + 1}$ is greater than 1, indicating growth in total factor productivity of green innovation from period t to period t + 1, and less than 1, indicating a decline. $M L E C_{i}^{t + 1}$ indicates a change in the technical efficiency of green innovation, where greater than 1 indicates that technical efficiency has grown and is closer to the production frontier, and less than 1 indicates that technical efficiency has declined and is further away from the production frontier. $M L T C_{i}^{t + 1}$ indicates a change in production technology, with greater than 1 indicating an advance in green innovation technology and less than 1 indicating a regression in green innovation technology.

2.3

Evaluation and analysis results of technological innovation efficiency in the catering industry

This paper takes China’s catering industry as a specific research object and evaluates and analyzes its green technology innovation efficiency in terms of static efficiency value and dynamic efficiency value.

2.3.1

Static efficiency values

According to the SBM-DEA model based on non-expected output, MaxDEA 6.6 Pro software was used to calculate the two-stage technical efficiency and total efficiency of green innovation in China’s restaurant industry.

1)

Time dimension analysis

First, the green technology innovation efficiency of China’s catering industry is analyzed from the time dimension, and the green technology innovation efficiency of China’s catering industry from 2014 to 2023 is shown in Figure 1. Among them, the first stage is the technology development stage and the second stage is the industrialization stage.

During the decade from 2014 to 2023, the green innovation efficiency of China’s catering industry generally shows an upward trend, with the green innovation efficiency of the technology development stage as well as the industrialization stage rising in ups and downs. The innovation efficiency of the technology development stage is 0.6149, much lower than that of the industrialization stage, which is 0.8751. After 2017, the total efficiency has slowly improved compared to the previous one. After 2014, the total efficiency maintains between 0.7 and 0.8, and the improvement of the total efficiency is not greatly affected by the technology development stage, and the power of the improvement mainly comes from the achievement transformation stage. The reason for this is that the government is implementing the new development concept and increasing its efforts in environmental remediation.

In the first stage, the static efficiency value of the technology development stage of China’s catering industry from 2014 to 2023 is 0.6149, with a basically stable performance and a slight increase. Among them, the technology development efficiency dropped sharply from 2014 to 2015, and the efficiency value fell into a trough in 2012. From 2016 to 2018, the efficiency of technology development grew slowly. After that, from 2019 to 2023, the efficiency value of technology development stabilizes at around 0.6 and oscillates up and down around this value.

In the second stage, the static efficiency value of the outcome transformation stage reaches 0.8751 from 2014 to 2023. The overall trend of growth is shown from 2014 to 2021, with the outcome transformation efficiency rising from 0.7348 to 1.0126. There are two small decreases experienced in 2015 and 2020.2015 is a fall from the previous year’s 0.7848 to the 0.6900 in the current year, and from 0.9327 to 0.8851 in 2020. 2021 to 2023 showed a more substantial downward trend, from the highest efficiency value of 1.0126 back to 0.8751.

2)

Spatial dimension analysis

Based on the SBM-DEA model, the green technology innovation efficiency of the catering industry in the three major regions of China is calculated as shown in Figure 2.

As can be seen from Figure 2, among the three major regions, the green innovation efficiency of China’s catering industry is highest in the east and lower in the west and center. The values of technology development efficiency in the eastern, central and western regions reach 0.7121, 0.4370 and 0.5087 respectively, and the values of achievement transformation efficiency are 1.0971, 0.6954 and 0.6900 respectively, corresponding to the total efficiency values of 0.9155, 0.6737 and 0.7066 respectively. The economically developed regions and the economically underdeveloped regions show a clear The economically developed regions and economically less developed regions show obvious regional disparities. At the same time, the efficiency values of the technology development stage and the achievement transformation stage also have obvious differences, and the efficiency value of achievement transformation is obviously higher than that of technology development.

In addition, the specific situation of green innovation efficiency of the catering industry in most provinces in China is shown in Table 1. From the perspective of provinces, the provinces with a total efficiency of more than 1 are concentrated in the eastern region, namely Hainan Province, Guangdong Province, and Beijing City. All of which are more developed provinces. The total efficiency of Hainan Province exceeding 1 is mainly caused by the high efficiency value in the achievement transformation stage, and the efficiency value in the achievement transformation stage is 5.5280. Guangdong Province and Beijing City both have higher technology development efficiency values, which are 2.5950 and 1.6487 respectively. There are three provinces with total efficiency values lower than 0.5, all of which are concentrated in the central and western regions, namely Shanxi, Guizhou and Gansu, with total efficiency values of 0.3978, 0.4644 and 0.4319, respectively.

Table 1.

Green innovation efficiency of Chinese catering industry

Region	DMU	The first stage	The second stage	Total band rate
Eastern Region	Hainan	0.9237	5.5280	2.2655
	Guangdong	2.5950	0.6817	1.3668
	Beijing	1.6487	0.8078	1.1641
	Zhejiang	0.6981	1.3203	0.9585
	Jiangsu	0.8366	1.0672	0.9666
	Shanghai	0.7217	1.0153	0.8447
	Tianjin	0.6159	0.9813	0.7566
	Fujian	0.4200	0.9737	0.6444
	Shandong	0.4116	1.0074	0.6532
	Hebei	0.3520	0.9497	0.5646
	Liaoning	0.4207	0.7360	0.5640
	Eastern Region	0.7088	1.1146
Central Region	Jilin	0.3531	1.1677	0.6277
	Henan	0.3759	1.0317	0.6208
	Hupei	0.4767	0.7756	0.6137
	Hunan	0.6669	0.5449	0.5835
	Anhui	0.8541	0.3752	0.5576
	Jiangxi	0.3172	0.7836	0.5114
	Heilongjiang	0.3583	0.7570	0.5103
	Shanxi	0.3166	0.4782	0.3978
	Central Region	0.4303	0.6997
Western region	Qinghai	0.4118	2.1140	0.9359
	Xinjiang	0.6119	0.9500	0.7748
	Chongqing	0.6226	0.7707	0.6732
	Sichuan	0.7175	0.5521	0.6285
	Ningxia	0.5294	0.6649	0.5893
	Shaanxi	0.4720	0.6843	0.5574
	Yunnan	0.623	0.4612	0.5604
	Guangxi	0.4798	0.6109	0.5438
	Inner Mongolia	0.2409	1.2080	0.5266
	Guizhou	0.7996	0.2917	0.4644
	Gansu	0.4069	0.4561	0.4319
	Western region	0.4844	0.6957

2.3.2

Dynamic efficiency values

1)

Analyzing the change of M index from a time perspective

The dynamic efficiency value (M index) of green technology innovation in China’s catering industry from 2014 to 2023 is shown in Table 2.

Table 2.

Dynamic efficiency of green technology innovation

Dynamic year	Changes in technical efficiency (EC)	Changes in technical level (TC)	M-index (TFP)
2014-2015	0.9584	1.0254	0.9707
2015-2016	0.9801	1.3889	1.3529
2016-2017	1.2528	0.6272	0.8067
2017-2018	1.0578	1.0717	1.1330
2018-2019	1.0989	0.9846	1.0819
2019-2020	0.9166	1.1019	0.9953
2020-2021	1.1864	0.8932	1.0671
2021-2022	0.9473	1.1257	1.0733
2022-2023	1.0280	1.0802	1.1012

From Table 2, it can be seen that the M index of China’s catering industry in 2014-2023 exceeds 1 in most years, and the years not greater than 1 are 2014-2015, 2016-2017, 2019-2020, and the average value of the M index is 1.0647, i.e., the efficiency of green technological innovation in the period of 2014-2023 maintains a continuous rising trend at a rate of 6.47% per year, and in the The value of green technology innovation efficiency in this period generally shows an upward trend. The change of M index is caused by TC and EC. From 2014-2023, the standard deviation of EC and TC is 0.11414 and 0.20322 respectively, so the fluctuation of technology level change (TC) is larger, and the fluctuation of technology efficiency change (EC) is more moderate, so the change of M index is mostly caused by technology level change (TC).

From 2014 to 2023, the dynamic efficiency value (M) index of green technology innovation in China’s catering industry has undergone a significant change, which can be divided into two stages for analysis. In the first stage for the year 2014-2018, TFP fluctuates substantially, and the green technology innovation efficiency vibration range is between 0.80-1.36, which is mainly due to the combined fluctuation impact of TC and EC. In 2018-2023, the technical innovation efficiency M index is in the second stage, showing a stable development trend and a slight increase. The TC and EC trends are opposite, and the magnitude of change is roughly the same, resulting in the M index being basically unchanged.

2)

Analyzing M index changes from a spatial perspective

The dynamic efficiency value (M index) of green technology innovation in the catering industry in most provinces in China is shown in Table 3. As can be seen from Table 3, the M-index of most regions in China is greater than 1, indicating that the green technology innovation efficiency of the catering industry in these regions has shown growth in the past 10 years. However, it is still important to point out that there are seven regions whose M-index does not exceed 1. These seven regions have an M-index that does not exceed 1, and the reasons for this are shown below:

Table 3.

Green technology innovation dynamic efficiency values

DMU	Changes in technical efficiency (EC)	Changes in technical level (TC)	M-index (TFP)
Anhui	1.0615	1.1144	1.1796
Beijing	0.9927	0.6893	0.6950
Fujian	0.9621	1.2152	1.1520
Gansu	1.0162	0.9362	0.9578
Guangdong	0.9996	1.0473	1.0426
Guangxi	1.0399	1.1443	1.1824
Guizhou	0.9805	0.9641	0.9277
Hainan	1.6016	0.7065	1.1182
Hebei	0.9834	1.1334	1.1376
Henan	1.0001	1.0101	1.0064
Heilongjiang	0.9522	1.0950	1.0321
Hubei	1.0870	1.1458	1.2845
Hunan	1.0727	1.1096	1.1668
Jilin	0.9897	1.0173	1.0179
Jiangsu	1.0240	1.0033	1.0578
Jiangxi	1.0214	1.1124	1.1675
Liaoning	0.9491	1.1546	1.1165
Inner Mongolia	1.0108	0.8928	0.9122
Ningxia	1.2735	0.7203	0.8955
Qinghai	1.0818	0.9321	1.0128
Shandong	0.9806	1.0157	1.0002
Shanxi	0.9928	1.0467	1.0354
Shaanxi	1.1166	1.1335	1.2722
Shanghai	0.9935	1.1019	1.1013
Sichuan	1.0694	1.1486	1.2077
Tianjin	0.9883	0.9477	0.9792
Xinjiang	1.0517	1.0699	1.1238
Yunnan	0.9673	0.9632	0.9519
Zhejiang	0.9956	0.9971	1.0168
Chongqing	0.9944	1.0779	1.0655
Mean value	1.0154	1.0063	1.0533

Beijing’s EC and TC values are 0.9927 and 0.6893, respectively, with both indicators less than 1. Gansu Province’s change in technology level is 0.9362. Guizhou Province’s change in technical efficiency is 0.9805 and change in technology level is 0.9641, with both indicators less than 1. Inner Mongolia and Ningxia’s change in technology level is 0.8928 and 0.7203, respectively, with both indicators less than 1. Tianjin’s change in technical efficiency and technology level is 0.9883 and 0.9477, respectively, with both indicators less than 1. Yunnan Province’s TC and EC are both less than 1. The change values of technical efficiency and technical level in Tianjin are 0.9883 and 0.9477 respectively, with both indicators lower than 1. The indicators of TC and EC in Yunnan Province are both lower than 1, at 0.9673 and 0.9632 respectively.

3

Convergence study of green innovation efficiency in the catering industry

To provide a comprehensive, accurate, and effective evaluation of the green innovation efficiency of the catering industry, this paper further analyzes the convergence of green innovation efficiency in the Chinese catering industry.

3.1

The concept of convergence

The concept of convergence mainly originated from the neoclassical growth theory, which modeled that technological progress is exogenous, the marginal return to capital shows a decreasing trend, developed economies have a high level of capital accumulation, the marginal return to capital is low, profit-seeking capital will move to the region with high marginal returns, i.e., the level of capital accumulation is lower than the flow of the region until the economic convergence of the regions.

Convergence analysis is an important method to study regional differences. Regional differences are not only manifested as static differences between regions in the cross-section at the same point in time, but also as a kind of dynamic change differences in time. The gap between different economies exists for a long time or the gap increases excessively, which will affect the efficiency of the overall economy, and is not conducive to the coordinated development of the inter-regional, according to the different research areas and contents, if the backward region’s research index grows faster than the developed region, this inter-regional difference will be narrowed, which will be manifested as a convergence phenomenon, and vice versa, showing the dispersion trend. The divergence trend may directly lead to the generation of the Matthew effect, exacerbating the phenomenon of inter-regional imbalance, thus jeopardizing the overall coordinated development, for which it is of great significance to carry out a reasonable convergence study on the change of regional differences. In general, the commonly used convergence analysis methods can be mainly summarized as σ-convergence, β-convergence and club convergence. σ-convergence is reflected by a single indicator or a combination of indicators, and β-convergence and club convergence are analyzed by econometric models.

3.2

σ-convergence of green innovation efficiency

Convergence focuses on the study of the deviation of the green innovation efficiency of the catering industry between different regions over time, if there is a decreasing trend, it indicates that there is σ convergence of the green innovation efficiency of the catering industry between regions. Among the methods to test σ convergence, statistical indicators are the simpler and easier methods with wide practicality. Indicators to measure the degree of divergence mainly include the coefficient of variation (CV), Searle’s index and so on.

1)

Coefficient of variation

The coefficient of variation, also known as the standard deviation coefficient, coefficient of variation, etc., is the most commonly used statistical indicator in the academic world to study σ convergence. It is expressed in the form of the ratio of standard deviation and mean in statistics, and the specific formula is: (9) $C V_{t} = \frac{1}{μ_{t}} \sqrt{\frac{1}{n} \sum_{i = 1}^{n} (y_{i t} - {\bar{y}}_{i})}$

Where: y_it(i = 1,2,3,⋯,n) is the green innovation efficiency of the restaurant industry in the i rd region in the t nd year, and ȳ_i is the average green innovation efficiency of the restaurant industry in each region in the tth year.

2)

Searle’s index

Searle index is a special form of comprehensive entropy index, entropy indicates the expected value of the amount of information, the closer the individual, the smaller the index value. Assuming that y_ij represents the green innovation efficiency of the catering industry in the jrd province and city in region i, the sum of the research objects $y = \sum_{i} \sum_{j} y_{i j}$ ; n_ij represents the population number of the jth province and city in region i, and the total population number $n = \sum_{i} \sum_{j} n_{i j}$ , the Searle’s index of the green innovation efficiency of the catering industry can be expressed in the following form: (10) $T_{p} = \sum_{i} \sum_{j} (\frac{y_{i j}}{y}) l n (\frac{y_{i j} / y}{n_{i j} /_{n}})$

3.3

β-convergence of green innovation efficiency

β Convergence refers to the fact that regions with lower initial levels of green innovation efficiency in the restaurant industry have faster growth rates relative to higher regions in order to achieve a reduction in the differences in green innovation efficiency in the restaurant industry between regions [28]. According to the different assumptions, β convergence can be further subdivided into absolute β convergence and conditional β convergence. This paper focuses on the absolute β convergence of green innovation efficiency in the restaurant industry.

The theory of absolute β convergence assumes that all the studied individuals have the same development structure and the same growth path, a common steady state can be realized through catching up, and the green innovation efficiencies of different regions will eventually converge to the same level over time. The theoretical model can be expressed in the following form: (11) $\ln (y_{i, t + T} / y_{i, t}) / T = α + β \ln (y_{i, t}) + ε_{i, t}$

where: ln(y_i,t+T/y_i,t)/T is the growth rate of green innovation efficiency in the catering industry in region i from t to t + T. α is the intercept term. β is the convergence coefficient term. ε_i,t is a random error term. In(y_i,t) is the initial level of green innovation efficiency in the F&B industry for Region i. If β is less than 0, it is considered that there is an absolute β convergence in the green innovation efficiency of the catering industry between regions, that is, the growth rate of the green innovation efficiency of the catering industry changes inversely to its initial value, and the region with a lower initial level will eventually catch up with the initially higher region through the high growth rate of the green innovation efficiency of the catering industry and reach the same steady-state level. While estimating the convergence coefficient of β, the convergence rate of green innovation efficiency in the regional catering industry θ and the convergence semi-life cycle required for lagging regions to catch up with developed regions τ can be further calculated: (12) $\begin{array}{l} θ = - \frac{\ln (1 + β)}{t} \\ τ = \frac{\ln (2)}{θ} \end{array}$

3.4

Convergence analysis of green innovation efficiency in the restaurant industry

Regarding the calculation of convergence using σ convergence, β convergence as the main calculation. First of all, for absolute σ convergence, the standard deviation, deviation or coefficient of variation of the research data are usually used for rough calculation. In this paper, the standard deviation is used to calculate the absolute σ convergence, while the absolute β convergence is calculated by constructing the correlation regression model, which is embodied in the value of the regression coefficients, and at the same time judging China’s green innovation from the four perspectives of joining and not joining the spatial factors, not joining the influential conditional variables and joining the influential conditional variables, in total. Efficiency and the change of convergence between the East, Middle and West regions.

3.4.1

Empirical analysis of σ-convergence

The absolute σ convergence values for China as a whole and for the East and West regions are shown in Figure 3. According to Figure 3, it can be seen that the convergence curve of the whole country is a fluctuating downward trend over time as a whole, indicating that there is a convergence of green innovation in the whole country. However, based on the data performance from 2022 to 2023, the standard deviation of green innovation development in the country has increased, which indicates the need to pay attention to the differences between the efficiency of green innovation. The development trend of the convergence curve in the eastern region from 2014-2023 shows that the standard deviation of the region has a slow fluctuating increase. However, the standard deviation of the research data in the east is always lower than that of the nation and the central and western regions, indicating that the development gap of the overall efficiency level in the east is smaller and the level is basically the same. The convergence curve of the central region shows a relatively large fluctuation pattern in the study interval of the sample, indicating that the regional differences between the central region are large, and the development of individual provinces in the central region has the phenomenon of a ladder, and in the two intervals of 2014-2016 and 2017-2020, it shows a flat fluctuation rise, and the convergence declines in 2021-2022, indicating that individual provinces and municipalities in the eastern provinces have a strong development trend, and the development speed is higher than other provinces in the region, with the efficiency of high-efficiency provinces in a steady state of efficiency, inefficient provinces continue to progress and develop, and the differences within the region are reduced after 2021. For the study of western places the standard deviation volatility is very large, of which the entire period from 2014-2018 is in a relatively large fluctuation pattern, and the differences within the region are gradually narrowed after 2018, indicating that all provinces and cities in the region are striving to develop, and in recent years have gradually reached a balanced development within the region. Among them, the regional differences in the east are the smallest in the whole country, and in the central and western regions, and the volatility is stronger in the central region.

3.4.2

Empirical analysis of absolute beta convergence

1)

Absolute β convergence traditional econometric model analysis

The theoretical model used for absolute β-convergence in this paper is shown in Equation (11). According to the length of the sample data study, t=3 is chosen, and the spatial effects are not considered at first, and only the traditional panel data (OLS) regression is established to see how β-convergence performs within the whole country of China and the East-Central-West region. The test results of the panel model effects are shown in Table 4. Where ***, **, * indicate significant at the 1%, 5% and 10% levels, respectively.

First of all, the F-test and the p-value of the absolute convergence β coefficient of the whole country and the three regions of the East and the West are all significant at the 1% level, which indicates that there is absolute β-convergence in the green innovation efficiency of the catering industry in the whole country and the three regions of the East and the West, indicating that an equilibrium between the whole country and the East and the West can be realized over time through the continuous development of the green innovation efficiency of the catering industry. This suggests that both the national and eastern and western regions can achieve equilibrium over time through the continuous development of green innovation efficiency in the restaurant industry.

Second, by comparing the convergence coefficients of the whole country with those of the east, center and west, it can be seen that the whole country, the east, the center and the west reach -0.098, -0.045, -0.141 and -0.172 respectively, and the p-values are all significant at the 1% level. The absolute value of the absolute coefficient is the largest in the west, indicating that the west has the fastest development speed. The central part of the country has a fast development speed relative to the east, and the east has the slowest development speed relatively speaking, indicating that there is a certain link between the development speed and the initial level, which brings about a relatively low development speed in the east, proving that the east, central, and west will realize further balanced development of the region under the influence of the theory of convergence when it is not affected by the rest of the external factors.

According to the convergence speed and half-life cycle calculated from the convergence coefficients, the western region has a convergence speed of 0.062 and a half-life cycle of 12.24, which is considerably faster compared to the east-central region and the whole country. The eastern region has the most sluggish convergence rate and longest half-life cycle, with a convergence rate of 0.15 and a half-life cycle of 49.23, respectively.

Table 4.

Estimation results of β convergence model under traditional panel model

Variables	National absolute β convergence	Eastern absolute beta convergence	Midsection absolute β convergence	Western absolute β convergence
ln(y_i,t)	-0.098*** (0.000)	-0.045*** (0.007)	-0.141*** (0.000)	-0.172*** (0.000)
R²	0.1672	0.0651	0.1834	0.2085
F	58.39	7.38	18.26	4.03
Convergence velocity θ	0.036	0.015	0.051	0.062
Half life cycle τ	21.41	49.23	14.65	12.24

2)

Absolute beta convergence spatial econometric model analysis

Due to the presence of regional spillover effects of green innovation, judgment of convergence results based on convergence alone is a prerequisite for the inclusion of spatial factors. Due to the national out of the East-Middle-West convergence speed with the average of the half-life cycle, following the inclusion of spatial factors under the study of the national province only, without considering the performance of the East-Middle-West inter-regional.

Introducing the adjacency weight matrix as a spatial weight matrix, adding the adjacency matrix to the traditional panel model, and then need to test to determine whether the analysis with spatial factors can be carried out, followed by the Lagrange multiplier (LM) test of the green innovation efficiency, and the results of the LM test are shown in Table 5.

Table 5.

Lagrange multiplier test

Check type	Statistic	P value
Moran’s error	2.614	0.009
LM-error	6.143	0.016
Roust LM-error	0.005	0.952
Roust LM-lag	7.132	0.009
Roust LM-lag	0.973	0.319

From the results of the LM test in Table 5, it can be seen that the P-value of Moran’s residuals is 0.009, which is statistically significant, and the error and lag of the model have passed the test of significance level. However, from the perspective of robustness consideration, the spatial lag model with a relatively small P value is selected for model fitting regression. In the Hausman test, the results rejected the original hypothesis, i.e., fixed effects were added for further fitting.

The national spatial absolute convergence β-convergence results are shown in Table 6. The F-statistics of the model are significant at the 1% significance level with a P-value, i.e., the model has a reference effect. It can be seen that for the fixed effects, an expansion is carried out and divided into three levels: spatial fixed, time fixed, and double fixed. The results show that the absolute beta convergence coefficients of the three fixed effects are not negative and the models are all very well significant, indicating that the models have research significance. After adding space, the national absolute β-convergence coefficient is higher compared to the β-convergence coefficient obtained from the traditional panel regression calculation. In particular, the performance of absolute beta convergence at the spatial fixed effects level and the performance of beta convergence coefficients at the double fixed effects level. The average speed of convergence under the three states is 0.0739 and the average half-life cycle is about 14.3145 years. It can also be found that the spatial lag model with double fixed effects has the greatest goodness of fit and is overall better than the other forms.

Table 6.

The fitting results of the national spatial absolute β convergence model

Variables	Spatial fixed effect	Time-fixed effect	Double fixed effect
ln(y_i,t)	-0.2614*** (0.000)	-0.0683*** (0.000)	-0.2641*** (0.000)
R²	0.531	0.259	0.672
F	7.544	1.926	3.795
Convergence velocity θ	0.0979	0.0241	0.0997
Half life cycle τ	7.0624	28.9867	6.8945

4

Conclusion

In this paper, we use the SBM-DEA model to realize the evaluation of green innovation efficiency of the catering industry in 30 provinces in China, and explore the convergence of green innovation efficiency in terms of σ-convergence and absolute β-convergence.

In terms of static efficiency values, the green innovation efficiency of China’s catering industry in general shows an upward trend from 2014 to 2023, the green innovation efficiency in the technology development stage as well as the industrialization stage rises in a fluctuating manner, and the innovation efficiency in the technology development stage (0.6149) is much lower than that in the industrialization stage (0.8751). In addition, the green innovation efficiency of the catering industry in eastern China is the highest at 0.9155, while that in western and central China is lower at 0.6737 and 0.7066, respectively. Economically developed regions and economically underdeveloped regions show obvious regional disparities. Meanwhile, the efficiency of results transformation is still significantly higher than the efficiency of technology development. In terms of dynamic efficiency value, the green innovation efficiency value (M index) of China’s catering industry in 2014-2023 exceeds 1 in most years, and the average value of the M index is 1.0647, which means that the green technological innovation efficiency of China’s catering industry in 2014-2023 maintains a continuous upward trend at a rate of 6.47% per year.

The results of absolute σ convergence show that the intra-regional differences in the east are smaller relative to the national and the central and western regions, for the national and the central and western regions in recent years, and the intra-regional differences in recent years have gradually narrowed, which indicates the improvement of the efficiency of innovation development in the central and western regions in the past 10 years. According to the β convergence to judge the convergence coefficient within the region, through the traditional convergence and spatial panel convergence of different forms of examination of the absolute β convergence, the results show that the development of the provinces there is a convergence of the characteristics of the absolute β convergence coefficients are negative, indicating that China’s provinces and regions will be along with their own continuous development, and ultimately reached the steady state level, and the west has the opportunity to be able to achieve the same level of efficiency value with the east. Secondly, the convergence speed of adding spatial factors is faster than that of traditional panel regression, indicating that spatial factors play an important role in the development of green innovation efficiency in the restaurant industry.

Funding:

This article is a phased achievement of the 2024 Guangxi Higher Education Institutions’ Young and Middle-aged Teachers’ Basic Scientific Research Capacity Enhancement Project: “Research on the Innovation of Study Travel Products in Beihai City from the Perspective of Tourism Big Data” (Project No. 2024KY1496).

Sprache:: Englisch

Zeitrahmen der Veröffentlichung:: 1 Hefte pro Jahr
Fachgebiete der Zeitschrift:: Biologie, Biologie, andere, Mathematik, Angewandte Mathematik, Mathematik, Allgemeines, Physik, Physik, andere

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Evaluation of green innovation efficiency in catering industry based on data envelopment analysis

Ying Zhong

Yanyan Yao

Xiaoting Huang

Online veröffentlicht: 21. März 2025

Eingereicht: 25. Okt. 2024

Akzeptiert: 14. Feb. 2025

DOI: https://doi.org/10.2478/amns-2025-0633

SchlüsselwörterSBM-DEA model, Malmquist-luenberger productivity index, Green innovation efficiency, Restaurant industry

© 2025 Ying Zhong et al., published by Sciendo

This work is licensed under the Creative Commons Attribution-NonCommercial-NoDerivatives 4.0 International License.

Schlüsselwörter
SBM-DEA model, Malmquist-luenberger productivity index, Green innovation efficiency, Restaurant industry