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A Quantitative Factorial Component Analysis to Investigate the Recent Changes of Japan’s Weight-Based Food Self-Sufficiency Ratio

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DOI: 10.4236/ajor.2016.61007    3,390 Downloads   3,598 Views   Citations


We investigate the weight-based food self-sufficiency ratio (WSSR) for Japan over a 50-year period (1961-2011) by applying factorial component analysis technique in order to measure the changes of the WSSR quantitatively. Quantitative data analysis is employed to determine the drivers of those changes. Numerical results show that Japan experienced a drastic decline in its food self-sufficiency ratio (FSSR) during the above period. The factorial component analysis shows that such a decline was caused by the changes in the FSSR of the food groups/items, not in the quantity of the food supply. A number of characteristics of those changes are presented and a list of major food groups that have major impacts on the changes is constructed. The findings in this paper reiterate the alarming food security problem in Japan and provide clear insight into the causes of this problem. The findings in this study pick up where previous studies have left off, aid the food-related policy-making process and identify new ideas for future food research.

Received 24 November 2015; accepted 22 January 2016; published 26 January 2016

1. Introduction

Living in the world’s third largest economy, Japanese enjoy a standard of living that most people in the world can only dream of. However, even though Japan is a prosperous nation, and Japanese have enough food to lead “an active and healthy life”, it is widely believed in Japan that the country has a problem that is theoretically faced only by the world’s poorer countries: food insecurity. Although this may sound ironic, even contradictory, some Japanese worry about an excessive nutritional intake of animal fats and unbalanced diet, many worry about Japan’s future food supply as its food self-sufficiency ratio (FSSR) has been declining over the past half century.

The FSSR is used to represent the magnitude of domestic production as a proportion of domestic utilization (including consumption). It is defined as the percentage of domestic production against domestic utilization. On a calorie basis, Japan’s FSSR has drastically dropped from 79% in 1960 to 39% in 2005, a drop of 40 percentage points in 45 years. This trend was publicly noted in 1973 and has been documented by Ogura [1] , Higuchi [2] and Saeki [3] , and more recently by, among others, Kako [4] , Tanaka and Hosoe [5] , Mashimo [6] , Yoshii and Oyama [7] , Trung, et al. [8] , Hayami and Godo [9] , Hayami [10] , and in various reports issued by Japan’s Ministry of Agriculture, Forestry and Fisheries(MAFF) (2000-2008) [11] .

These studies focus on the exogenous elements that are factors of the decline of Japan’s WSSR and economic implications both for supply and demand of food. Many have given attention to domestic and international economic policies. However, few have examined the endogenous factors that account for the downward trend in the FSSR. It is important, though, to investigate the drastic change in Japan’s FSSR in more detail, from the inside out in order to gain an overall understanding of the situation. Such research would help policy makers in planning new directions for the country’s future food supply and food policy.

We seek to enrich the literature by performing quantitative factorial component analysis to investigate, in detail, the endogenous elements that have affected Japan’s WSSR over the 50 years from 1961 to 2011. In the next section the paper starts by constructing and presenting a weight-based WSSR for Japan. Then in Section 3 the ratio will then be decomposed into factorial components for quantitative analysis. The characteristics of the changes will be analyzed to provide insights into the most important factors that have driven down Japan’s WSSR. The findings, which are presented in Section 4, will have implications for policy directions. Summary and conclusions are given in the final Section 5.

2. Japan’s Food Self-Sufficiency Ratio and Its Past Trend

Calorie intake is often used in Japan as the basis for calculating the nation’s FSSR. The FSSR on a calorie basis is defined as the percentage of the net calorie intake per capita per day supplied by domestic production over the total net calorie intake per capita per day. Japan’s FSSR on a calorie basis drastically fell from 79% in 1960 to 39% in 2005 (Kako [4] ), and has stayed around 39% thereafter until now. These figures, with minor adjustments, were widely used in academic papers and policy discussions in MAFF (various reports/papers 2007-2009), Kako [4] , Tanaka and Hosoe [5] , Mashimo [6] , Yoshii and Oyama [7] , Trung, et al. [8] .

There are other methods to measure a country’s FSSR. One measure using weight is called the “WSSR on a weight basis” (WSSR). Similarly, the FSSR measure based on money is called the “FSSR on a monetary basis” (MSSR). Japanese make little use of the MSSR while the WSSR is rarely given official attention in Japan. Japanese government, however, has announced the target for the FSSR on a calorie basis as 45% in 2025 even though it seems to be very difficult to be attained as the current value is still low as of 39% in 2014.

This paper, however, opts to use a more internationally recognized approach to calculate Japan’s FSSR so that a comparative perspective may be obtained. This paper employs FAO definitions and utilizes its Food Balance Sheets to reassess Japan’s data from 1961 to 2011 so that a comprehensive picture of the country’s food supply patterns during that period can be obtained. Data for those sheets were standardized and updated in December 2009. We have used the most recent data set FAO-STAT as the 2011 data is the latest one at this stage.

Using the FAO’s internationally acknowledged methods of data classification for representing actual agricultural production, a measure of Japan’s FSSR on a weighted basis (hereinafter, the “WSSR”) is developed to estimate the magnitude of domestic production in relation to overall domestic utilization. Let N be the set of food groups/items concerned. Then Japan’s FSSR, on a weight basis, denoted by WSSR, is formulated as follows:



While (1) is used to obtain a value for the FSSR of all food groups/items, the self-sufficiency ratio of each food group/item i on a weight basis (%), denoted by WSSRi, can also be calculated in a similar manner.


Likewise, a food import dependency ratio for Japan (the “FIDR”) on a weight basis (%) is developed to assess the importance of imported food in the country. The FIDR expresses the magnitude of imports in relation to domestic utilization and is formulated in a similar manner to its WSSR counterpart except for the difference in the numerator, where domestic production is replaced by the value for import, as follows.


The numerical results for WSSR and FIDR were derived by computing the values for (1), (2) and (3) using the FAO 2010 data for Japan’s Food Balance Sheets from 1961 to 2011. The values are given in Table 1 and graphed in Figure 1. Twenty major food groups (MFG) were used to compute the ratio. The group labeled “Miscellaneous” is omitted due to missing data throughout the reference period2. The use of all 20 MFG allows for a consistent measure of the total food supply and utilization in the country. These MFG and the food items included in each grouping are given in Table 2.

The results show that the values for both the WSSR and the FIDR changed drastically over time in ways consistent with the views of those concerned about Japan’s future food supply and import dependency. It is obvious from the graph in Figure 1 that the values for the WSSR fell sharply from 87% in 1961 (or an average of 80% in the 60s) to an average of 54% in the first five years of the new millennium. It is a drop of nearly 34 percentage points in 45 years, or a loss of 39% in value. The values for FIDR rose from just above 14% in 1961 to more than 49% in 2005. That is an increase of 35 percentage points over the same period, or a 2.5-fold gain in value. In the meantime, food supply in Calories (kcal) continued to rise as Japanese sought a higher living standard and the economy grew. The calorie intake rose from 2468 Calories per capita per day in 1961 to 2752 Calories in

Table 1. WSSR and FIDR on a weight basis (%), and Food supply (kcal/capita/day) (kcal), Japan 1961-2011.

Figure 1. Japan’s per capita per day calorie intake (left axes) and WSSR, FIDR (right axes).

1972, peaking at 2859 Calories in 1996 before slightly decreasing to 2743 Calories in 2005. That was a 11% increase in daily calorie intake over the last half century. Nevertheless, the 2005 level was just about that of the early 1970s, implying no net improvement in calorie intake over the 35-year period.

Taken altogether, the three trends indicate that while the quality of life is improving, Japan produces only half of its food needs and has come to depend on foreign imports for the other half. Setting aside differences in the

Table 2. 20 MFG and the items included.

statistics used, the results correspond to the findings described in the MAFF papers and in the previous studies by Kako [4] , Tanaka and Hosoe [5] , Mashimo [6] , Yoshii and Oyama [7] , Trung, et al. [8] , Hayami and Godo [9] , and Hayami [10] .

Whether the trends are cause for “alarm” depends on one’s point of view. Many other variables also shape the political decision-making process in this globalized era. One could say that these trends might raise much concerns in both domestic and international arenas, given their impact both on Japan’s food production, prices and trade, and the world’s needs for overall global sufficiency.

In addition to realizing the changes in both WSSR, FIDR and calorie intake, one should also note that the pattern of food consumption in Japan has changed considerably over the past 50 years. Mashimo [6] has commented on the reasons for such changes3, and studied three different patterns of Japanese food consumption in 2005. The first pattern was the status quoin 2005. The second pattern was a set of food intake and nutritional data recommended by the Ministry of Health, Welfare and Labor (MHWL). This pattern has been created as the ideal for Japanese to maintain their health, avoiding lifestyle-related sickness (MHWL pattern). And the third pattern was a set of food requirements based on the daily meal menus organized by Setsuko Shirone, an expert of sustainable food consumption and organic agriculture. Mashimo [6] called this the Chisan-chisho pattern (LP-LC pattern), after a popular movement that encouraged local production and local consumption in Japan. In 2005, according to the MHWL pattern, the ingestion of grains, potatoes and vegetables would increase, while the consumption of meat, milk products, sugar and fat would drastically decrease. This tendency was even more radical in the LP-LC pattern. The difference was the high amount of marine product intakes that was still considered to be possible. All of this, however, consisted of small fish and coastal fish, as well as the continued consumption of other domestically available marine species (Mashimo [6] ).

3. Method and Numerical Results for Factorial Component Changes

3.1. Method for Measuring Changes

This part of the paper employs a factorial component analysis to assess the weight of endogenous factors that might account for the decline in the WSSR. The annual total change in the WSSR is broken into two major factorial components: (1) the change due to the WSSR change of each MFG component, and (2) the change due to MFG’s quantity supply change. These two factors are then compared to examine the irrelative impact on the WSSR.

Recalling the definition of food self-sufficiency ratio, WSSR is defined as the magnitude of domestic production in relation to overall domestic utilization. In other words, WSSR is the fraction of the total domestic utilization times its own self-sufficiency ratio (which equals domestic production) over the total domestic utilization. In mathematical terms, WSSR―hereinafter denoted by R―is defined as follows:



The first derivative of (4) with respect to time shows that changes in R consists of both changes in pi and wi. In general terms, the annual change in Japan’s food self-sufficiency ratio is the combination of a component change in the self-sufficiency ratios of the concerned MFG and a component change in the quantity of those MFG’s supply. Specifically, a small change in the value of R, denoted as ∆R, can be decomposed into two components corresponding to the SSR change and the quantity change respectively, as follows:


Denoting the above “annual” changes corresponding to the changes for R, pi and wi as ∆R, ∆pi and ∆wi, respectively, we can rewrite the expression in (5) as follows.


Let be the total supply for domestic utilization, then the right-hand-side (RHS) terms in (6) could be rewritten as:




Replacing (7) and (8) in (6) yields



Note that the left-hand-side (LHS) in (9) is the total annual change in Japan’s food self-sufficiency ratio. The first term of the RHS in (9) is the factorial change in the major food groups’ self-sufficiency ratios, and the second term is the factorial change of their supply quantities.

3.2. Numerical Results for Factorial Component Changes

The numerical results for the WSSR for each of the 20 MFG, and the values for all the terms in (6) were computed through (9) using the 2010 FAO data for Japan’s Food Balance Sheets from 1961 to 2011. The results are presented in the Table A in the Appendix and in Table 3 below.

Table 3. Numerical results for W, R, ∆R, ∆Rp and ∆Rw.

Using the breakdown in formula (6), we can map the relations between WSSR’s annual factorial changes, ∆Rp and ∆Rw, and the total changes ∆R. Using the computed data, the graphs in Figure 2 show those relations and the 3-period moving average trend for ∆R.

Figure 2 shows that a strong correlation between the factorial change in MFG’s WSSR (∆Rp) and the total change in WSSR (∆R) does exist, but we cannot find a relation between the factorial change in MFG’s quantity supply (∆Rw) and ∆R. The graphs show that ∆Rw fluctuated in a narrow band close to the origin0.0 and registered mostly positive values except for the period after year 1995. On the other hand, ∆Rp and ∆R took on mostly negative values and moved in close tandem with each other in a much wider fluctuation, mainly below zero. Positive values and minor adjustments or changes in MFG’s supply tend to stabilize and mitigate the total changes in WSSR. Nonetheless, changes in MFG’s WSSR diminish that effect as sharp falls tend to cause a drastic fall in the total change in WSSR. The 3-year moving average trend line also shows that, on average, ∆R moved in a wide band far below zero in a way that reflected the broad negative fluctuation of ∆Rp, and cancelling out the positive effect brought about by ∆Rw. The moving average stays mostly below zero, implying and verifying the fact that WSSR declines most of the time.

This data analysis shows that the declining trend of WSSR is mainly due to the declining trend of the MFG’s WSSR rather than due to the changes in MFG’s quantity supply.

3.3. Trend Analysis on the Factorial Change

We analyze the time series trend of factorial component changes in order to investigate the change in the WSSR in more detail. We divide the whole time span of 1961-2011 into four sub-periods, trying to find the specific characteristic of the three elements concerned (∆R, ∆Rp and ∆Rw) in each of these four sub-periods, which we denote by I, II, III, and IV, respectively.

Sub-period I (1961-1976): This is the longest sub-period, characterized by large negative values for ∆R and ∆Rp. During the sub-period the rise in the values for ∆Rw kept the values for ∆R from falling more than they did. This period corresponds to the time when many food-related policies, such as the rice diversion program, which started in 1970 to reduce the domestic rice production by 30% - 40%, thus policy changes were adopted in Japan. The period also saw the “westernization” of Japanese diets. Although agricultural production in this period performed satisfactorily, new demands created huge shortages in food items which were not produced domestically. The outcome was a sharp fall in the values of ∆Rp for many food items (i.e., MFG) which led to the sharp fall in the values of ∆R (i.e., WSSR). Major falls occurred in rice, grain and wheat in the “Cereals” MFG and in potatoes and sweet potatoes in the “Starchy Roots” MFG. On the other hand, weights of vegetables, fish, seafood, milk and fruits increased in a large scale, which made the values of ∆Rw rather stable.

Sub-period II (1977-1984): This is the shortest sub-period, lasting only eight years, where the fluctuations in ∆R and ∆Rp were within a narrow band. Again in this sub-period, the values for ∆Rw remained mostly highly and strongly positive. ∆R remained only slightly negative through this period, and for some years even rose into positive territory. This period came after a long period of decline in the WSSR that had begun to alarm Japanese in the early 1970s, following the Oil Crisis that rocked Japan’s economy. A mild “return to local foodstuff” saw the WSSR rise somewhat. However, Japan’s relatively open agricultural trade policy tended to offset the return, and the WSSR fluctuated during this time. Major contributors to the fluctuation were grain and wheat in the “Cereals” MFG. New impacts came from wine and alcoholic beverages in the “Alcoholic Beverages” MFG, the “Vegetables” MFG, and a range of foreign fruits from the “Fruits-Excluding Wine” MFG.

Sub-period III (1985-1996): During this period, Japan returned to the pattern that had been found for the first sub-period. It was characterized by negative values for ∆R and ∆Rp (though with slightly smaller values). The values for ∆Rw were positive from 1985-1989. Then they turned negative, which, together with ∆Rp, amplified the negative values being registered for ∆R. This period marks the beginning of Japan being the world’s largest net food importer. High volumes of imports in wheat, grain in the “Cereals” MFG, in potatoes in “Starchy Roots”, in wine and alcoholic beverages in “Alcoholic Beverages”, in tomatoes, onions and other vegetables in “Vegetables”, in apples, bananas, oranges, pineapples, grapes in “Fruits-Excluding Wine” contributed mostly to low negative values in ∆Rp. The new commodities were marine fish and other seafood in the “Fish, Seafood” MFG, and bovine meat, mutton and goat meat in the “Meat” MFG.

Sub-period IV (1997-2005): This was a stable, but all negative period. The values for ∆Rp and ∆Rw were negative almost all time, thereby keeping those for ∆R in the negative zone. The moving average was quite

Figure 2. ∆Rp, ∆Rw, ∆R and its 3-year moving average of ∆R.

smooth and the negative scale was not that as much as that of the former three sub-groups. Thus the “stabilized period” is explainable. After three periods of sharp declines and fluctuation, the values for ∆Rp and ∆Rw seem to “adapt” themselves to the new domestic demands and dietary habits. This results in a more stable set of slightly negative values for ∆R. The commodities remain those noted above.

4. Investigation on the Relation among Factorial Component Changes

4.1. Impact of Factorial Component Changes on the Total Change

To analyze the impact of factorial component changes on the total change, the values for ∆Rp and ∆Rw are individually regressed against those for ∆R. Figure 2 plots the two combinations (∆R, ∆Rp) and (∆R, ∆Rw) to represent the comparative relation between the two components and the total change. We note that, firstly, the values for the total change ∆R vary within an interval ranging from −3.0 to 1.0. Secondly, the values for the factorial component change ∆Rp range within the same interval −3.0 < ∆Rp < 1.0. Thirdly, the values for the factorial component change ∆Rw range in a much narrower interval −0.5 < ∆Rw< 0.5.

The graphs in Figure 3 show that the data points for the (∆R, ∆Rp) combinations, letting ∆R and ∆Rp expressed by x and y, respectively, are best explained by the single variable linear regression model y = 0.874x − 0.124 (with R2 = 0.897). This means that the component change ∆Rp is generally explained by the total change ∆R with almost 90% goodness of fit. Moreover, only one-fifth (20%) of the (∆R, ∆Rp) combinations, i.e., 9 out of 50 combinations, are located in the first coordinate while almost 70%, i.e., 37 out of 50 combinations, are in the third coordinate, meaning the negative change in the values for ∆R is mostly attributed to the negative change in the values for ∆Rp, not that of those for ∆Rw. In other words, the declining trend of WSSR is attributed to the decline in the self-sufficiency ratios of the foodstuff themselves, not that of the change in the food supply quantity.

On the other hand, the graph does not show a satisfactory correlation for the (∆R, ∆Rw) combinations. These combinationsscatter along a narrow rectangle given by −3.0 < ∆R < 1.0, and −0.5 < ∆Rw < 0.5, meaning that the factorial component ∆Rw has not changed on a large scale in the past 45 years and has not contributed greatly to the total change ∆R. We also note that data points in the first coordinate (i.e., positive values for both ∆R and ∆Rw) stay close to the origin, implying not much change and impact on ∆R. Positive changes in ∆Rw are mostly reflected in the increase in Calorie supply (kcal/capita/day) rather than in ∆R and WSSR as a whole.

4.2. Relation between Factorial Components

Table 4 presents the frequency of the values for ∆Rp and ∆Rw during the reference period. It shows how they are distributed, over 51 years as a whole (50 years of changes), and in each of the above-mentioned four sub-per- iods in particular. It can be seen from the table that the number of years when the values for ∆Rw are nonnegative and that when the values for ∆Rw are negative are equal as 23 and 27, respectively, thus they are not so different.

Figure 3. Plots of (∆R, ∆Rp) and (∆R, ∆Rw).

Table 4. ∆Rp and ∆Rw frequency.

On the other hand, regarding the values of ∆Rp, they are positive only 12 years among 50 years while other 38 years show negative values.

In the sub-period I only 2 years out of 15 are in the 1st coordinate, i.e., ∆Rp and ∆Rw are both positive while other 6 years are in the 2nd coordinate, i.e., ∆Rp negative and ∆Rw positive, and 7 years are in the 3rd coordinate, i.e., ∆Rp and ∆Rw are both negative. In the sub-period II 3 years are distributed in the 1st coordinate and 1 year is in the 4th coordinate, i.e., ∆Rp positive and ∆Rw negative while 2 years are in the 2nd and 3rd coordinates, respectively. In the sub-period III 2 years out of 12 in total are in the 2nd coordinate while remaining 8 years are in the 2nd coordinate and 2 years are in the 3rd coordinate. In the sub−period IV only 1 year out of 15 in total is in the 1st coordinate while remaining 10 years are in the 3rd coordinate and only 1 year and 2 years are exceptionally in the 2nd and 4th coordinates, respectively.

Thus, we find that most sub-periods, excluding II, show dominatingly negative ∆Rp no matter how ∆Rw are valued. This trend in the sub-period I is due to the decrease (increase) in supply (import) in majorly grains. In the sub-section III similar trend comes from decreasing supply of rice, vegetables, fruits, meat and fish. Sub-pe- riod IV shows the decreasing trend of major food items excluding meat corresponds to the negative ∆Rw. Sub- period II shows that both ∆Rp and ∆Rw are close to zero.

Figure 4 graphs the time series changes in the four sub-periods, and for the 1962-2011 period as a whole, relative to a center point. We find that ∆Rp and ∆Rw follow two different paths unrelated each other. In all four sub-periods, ∆Rw tended to be stably staying around the circular line corresponding to the value zero while ∆Rp unsteadily scattered along the scale and mostly staying in the area corresponding to “negative” points. We find that the graphs reiterate ∆Rp’s tendency of being mostly negative for sub-periods I and III while it is mostly close to ∆Rw’s for sub-periods II and IV.

We also note that the values of the center points are all different for these figures while the scale for each sub-period is also different. This means ∆Rp and ∆Rw vary in each sub-period as we see the different shapes of

Figure 4. ∆Rp and ∆Rw in 4 sub−periods and all.

the graphs. Moreover, we learn that there were but 8 years (out of 50, or 16%) in the reference period where ∆Rp and ∆Rw took on positive values, and stayed close to each other. Those were in 1965, 1975, 1978, 1981, 1982, and 2008. It explains why the total change ∆R were mostly negative, and WSSR declined during the 1961-2011 period.

4.3. Impact of MFG on the Factorial Component Changes

Of all 20 MFG concerned, the impacts they have on ∆Rp and ∆Rw (and, therefore, on ∆R) are quite different. We compute minimum, median and maximum of ∆Rp and ∆Rw for all 20 MFG in the reference period to observe such impacts. Table 5 presents these minimums, medians and maximum, and Table 6 lists the top 10 MFG with the greatest impacts on ∆Rp and ∆Rw, respectively. The ranking is based on (1) the scale of the impact with respect to the median, and (2) the nature of MFG’s fluctuation pattern. These Table 5 and Table 6 are obtained from calculating numerical results given in Table A in the Appendix.

From Table 5 and Table 6 we find that regarding the median of ∆Rw, changes of supply for “Cereals”, “Alcoholic Beverages”, and “Fish, Seafood” give rather positive impacts while only “Starchy Roots” gives rather negative impact. Negative impact due to “Starchy Roots”, even though small, may result from the fact that they are transformed into some other consuming foods rather than directly consumed in the market. Also regarding the median of ∆Rp, only “Sugar & Sweeteners” brings small positive impact while other “Cereals”, “Fruits”, and “Fish, Seafood” bring large negative impacts. These large negative impacts may result from the fact that we have been importing these foods such as “Cereals”, “Fruits”, and “Fish, Seafood” constantly and largely as major foods in Japan.

As shown in Table 5 and Table 6, we see that maximum values with respect to ∆Rp are very high for “Cereals”, “Starchy Roots”, “Sugar & Sweeteners”, “Alcoholic Beverages”, and “Fish, Seafood”, and their minimum values are generally very small, which implies that these foods including “Vegetables” and “Meat” have both large positive and large negative impacts on our ∆R. The “Cereals” MFG has the second largest and highly important impact on both ∆Rp and ∆Rw. The “Fish, Seafood” MFG has more impact on ∆Rp and less on ∆Rw while “Meat” and “Vegetable Oils” have almost the same importance in affecting ∆Rp and ∆Rw. The MFG “Cereals”, “Starchy Roots”, “Fish, Seafood”, “Meat”, “Vegetables”, “Vegetable Oils”, “Milk”, “Alcoholic Beverages” are presented in both columns, implying their importance in Japanese diets. The missing MFG in the list (“Sugarcrops”, “Treenuts”, “Oilcrops”, “Spices”, “Offals”, “Animal Fats”, “Aquatic Products, Other”) reveals that food policy-making process can target these MFG without much impact on WSSR. On the other hand, policy makers should be careful when targeting MFG in the Top 10 list in order to avoid an unwanted impact on ∆Rp and/or ∆Rw, and therefore on ∆R and WSSR.

Table 5. Impact of MFG on ∆Rp and ∆Rw.

Table 6. Top 10 MFG affecting ∆Rp and ∆Rw.

5. Summary and Conclusions

It is inarguable that food self-sufficiency has become a very serious policy issue in Japan. Local scholars and bureaucrats believe the country’s Food SSR has been as low as 40% in the recent trend from 2005 until now on a calorie basis. The results in this paper show a higher value, 53%, on a weight basis. Yet, it is still low, compared to that of 87% in 1961. It is a drop of nearly 34 percentage points in 50 years. This situation puts a pressure on the country’s agriculture sector and leaves national food security and national safety vulnerable.

By breaking ∆R into two major factorial component changes, ∆Rp and ∆Rw, we were able to analyze and find that it was the change in the major food group’s self-sufficiency ratio, ∆Rp, that drove the change in ∆R, not that of the change in the major food group’s quantity supply, ∆Rw.

The trend analysis concludes that ∆Rp and ∆Rw, and that ∆Rp have a stronger and a greater impact on ∆R while there is no explicit relation between them. Thus we concluded that the decline of ∆R was mostly due to the decline in major food group’s self-sufficiency ratio (∆Rp). We also found that the values for ∆Rp and those for ∆R can be well explained by a linear equation, with an almost 90% goodness of fit. On the other hand, we could not find any satisfactory expression to explain the values of ∆Rw and those for ∆R.

We also divided the reference period into four sub-periods to investigate the characteristics of the changes and to explain WSSR’s overall declining trend. We noted the differences in the characteristics of each sub-per- iod, and found the commodities that contributed to such characteristics.

We also computed and listed the top 10 MFG that had the greatest impacts on both ∆Rp and ∆Rw in particular and ∆R as a whole. Among them, the “Cereals” MFG proved to have had the major and most highly important impact on both ∆Rp and ∆Rw. The MFG “Starchy Roots”, “Fish, Seafood”, “Meat”, “Vegetables”, “Vegetable Oils”, “Milk”, “Alcoholic Beverages” all displayed their importance in the Japanese diets. These are the MFG that the policy-making process needs to pay more attention to in order to avoid a negative impact on ∆Rp and/or ∆Rw, and thus on ∆R and WSSR.

By studying ∆Rp and ∆Rw―the endogenous factors of WSSR, the paper partly fills the gap in the literature on Japan’s food problems. The findings in this paper lead to many suggestions and implications for both policy makers and food researchers. From both the research and policy-making points of view, one obvious question, among others, would be to what extent WSSR can be recovered. What would be the maximum sustainable WSSR? In an attempt to find the answer to such questions, a study on food network flow programming is conducted. The optimal results from such optimization model would be significant for further investigation of food security in Japan.


Table A. 20 Major food groups’ self-sufficiency ratios, Japan 1961-2011.


1FAO, “Rome Declaration on World Food Security and World Food Summit Plan of Action”, World Food Summit, Rome, 13-17 November 1996.

2The major food groups were: (1) Cereals-Excluding Beer; (2) Starchy Roots; (3) Sugar Crops; (4) Sugar & Sweeteners; (5) Pulses; (6) Tree Nuts; (7) Oil Crops; (8) Vegetable Oils; (9) Vegetables; (10) Fruits-Excluding Wine; (11) Stimulants; (12) Spices; (13) Alcoholic Beverages; (14) Meat; (15) Offals; (16) Animal Fats; (17) Eggs; (18) Milk-Excluding Butter; (19) Fish, Seafood; and (20) Aquatic Products, Other.

3Mashimo argued that dietary changes in Japan dated back to the 1960s and 1970s with the rice diversion program and the “westernization” of the Japanese dietary habit. See Mashimo (2008) for details.

Cite this paper

Yoshii, K. and Oyama, T. (2016) A Quantitative Factorial Component Analysis to Investigate the Recent Changes of Japan’s Weight-Based Food Self-Sufficiency Ratio. American Journal of Operations Research, 6, 44-60. doi: 10.4236/ajor.2016.61007.


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