The Potential of Hydroponic Kit-Based Growing on a Self-Fertigation System for Pagoda Mustard (Brassica narinosa L) Production

Agricultural land has been converted into settlements following the population growth in various parts of the country. The productivity of horticulture, particularly pagoda mustard (Brassica narinosa L), decreases with the narrowing of fields. The main milestone as a promising solution to overcoming this issue is applying the hydroponic technique. This study aims to analyze the potential of hydroponic kit-based growing on a self-fertigation system for pagoda mustard production. In contrast to general hydroponic, the proposed hydroponic kit is supported by a smart valve component as a unique novelty used for the automatic distribution of nutrients without electrical power (zero energy). The mustard seeds were sown on rockwool for two to three days in a dark room and placed in the sun for seventeen days. A total of 50 pagoda mustard seeds were arranged evenly on a self-fertigation system tray following a zig-zag planting pattern for forty days. The seed has the following morphological characteristics: average height of 22.88 cm, biomass width of 26.42 cm, root length of 23.4 cm, and weight of 241.5 g. Furthermore, the production requires a total fertigation consumption of 186 L (equal to 0.0935 L/plant day−1) with an actual crop coefficient between 0.01 and 0.54. The proposed system shows good performance for mustard growth with a uniformity value between 80 and 89%. Finally, hydroponic kit-based growing on a self-fertigation system can be applied in various areas to produce and maintain a sustainable food supply.


Introduction
Many countries rely heavily on mustards as a staple food in their diet. Tis is because the seed contains many polyphenolic compounds, including vitamins A, C, and E, calcium, and iron [1,2]. Additionally, they provide an important source of dietary antioxidants and have high radical scavenging activity in preventing various chronic diseases such as cancer and cardiovascular disease [3,4]. Based on the Central Bureau of Statistics [5], mustard production in Indonesia will reach approximately 667 thousand tons in 2020. Te variety with a great economic value is the pagoda mustard (Brassica narinosa L), sold for IDR20,000 per 500 grams. Out of the 34 provinces in Indonesia, West, Central, and East Java are the top three producers of mustard.
However, the country's growing population has resulted in land conversion issues, directly narrowing agricultural land [6][7][8]. Te narrower the land, the lower the horticulture productivity. Te main milestone as a promising solution to overcoming this issue is applying the hydroponic technique. Tis is a cultivation technique using water or nutrient solution as a growing medium, known as soilless culture [9]. Te main advantages are [10]as follows: (1) possible use of areas unsuitable for conventional agriculture, such as dry and degraded land; (2) plant independence for weather conditions; (3) year-round cultivation; and (4) reducing the use of labor-intensive activities such as weeding and soil preparation. Te activity in hydroponics is also arguably lighter than conventional farming [11,12]. Terefore, applying hydroponics to cultivate mustard is a solution to the massive conversion of agricultural land and increased productivity.
In hydroponics, water and nutrients are often supplied to plants using a fertigation system, which involves the injection of fertilizer into the irrigation stream. Some of the well-known systems include deep fow technique (DFT), nutrient fow technique (NFT), drip irrigation, Dutch bucket, and foating raft [13,14]. However, the main drawbacks of these fertigation systems are (1) dependence on electricity throughout the cultivation of crops; (2) reasonably high investment and operational costs; (3) wasteful of water and nutrients; and (4) inefcient use of energy; and (5) unsuitable for underdeveloped regions. Terefore, this study proposes a breakthrough in environmentally friendly hydroponic technology based on a self-fertigation system, also well-known as Autopot [15][16][17]. Self-fertigation system provides nutrients automatically without using electricity (zero energy) throughout the cultivation. Tis advantage will lead to low investment and operational costs. As a result, it has grown rapidly in various regions in Malaysia [18], Australia [19,20], and Saudi Arabia [17].
Hydroponic kits powered by self-fertigation systems are available with several trademarks, such as Autopot ® Systems [18] and AQUAvalve5 [19], with a competitive price depending on the specifcations. However, this research has designed the system supported by a smart valve component as a unique novelty used for automatic nutrient distribution compared to the type mentioned above. Tis is an improvement over previous technology, scientifcally reported by Bafdal et al. [15]. Te registered trademark for the system used is smart watering [20]. In the proposed self-fertigation, the smart valve component is designed to follow the principles of pressure and gravity. It signifes that the valve will open and close automatically based on the predetermined height, allowing the distribution and utilization of nutrients to operate efciently and cost-efectively. Tis kind of technology is very suitable to be applied in areas that do not have access to electricity.
According to research reports, the self-fertigation technology efectively increases crop output by distributing nutrients precisely [15,[21][22][23]. Terefore, this system is suitable for horticultural commodities requiring large water and a relatively short harvest time. Te implementation has covered various horticultural commodities such as cherry tomato, paprika, chili, cucumber, and wheat [15,17,21,24]. However, no information about the application of mustard has been published to date. Tis research can also provide a new perspective on applying a self-watering system because each plant commodity has its characteristics. Terefore, this study aims to analyze the potential of a hydroponic kit based on the self-fertigation system for mustard pagoda production. Tis information is benefcial for various parties, especially growers, to efectively and efciently run the production process.

Pagoda Mustard Cultivation.
Pagoda mustard is one of the best vegetable plants because of its distinctive leaf form [25]. Te seeds were obtained from Known You Seed Indonesia, Ltd. Pagoda mustard cultivation stages, including seeding, transplanting, and maintenance. First, the seeding process was carried out using rockwool planting media and placed in a dark room for two to three days. Second, the mustard seeds were removed and placed under the sun for seventeen days. True leaves are the frst indication that the pagoda mustard is ready for transplantation.
Te transplanting process was conducted from the seeding tray into the net pots and was transferred to the tray of the self-fertigation system until the harvest period. A total of 50 pagoda mustard seeds were placed evenly on the selffertigation system tray following a zig-zag planting pattern ( Figure 1). Te planting distance was fxed at 20 cm since mustard has high biomass. Additionally, the roots of plants grown in net pots were permitted to protrude, allowing them to grow freely and be exposed to nutrients directly.
Te next phase is maintenance, which tries to sustain plant life and suitable habitat. Daily maintenance of pagoda mustard addressed its water and nutrient needs. AB-mix fertilizer was utilized, combined with 5 L of water before applying. Te nutrient solution was stirred until smooth to prevent the precipitation of fertilizer.

Rooftop Greenhouse.
In this study, pagoda mustard was grown on the protected rooftop of a building at the Laboratory of Rooftop Urban Farming, Universitas Padjadjaran, Indonesia. It is located at coordinates 06°55′ 23.4″ South Latitude and 107°46′ 19.3″ East Longitude with an elevation of 794 masl. Tis location is suitable to support pagoda cultivation because they can produce well at an elevation of 250-1200 masl.
Rooftop cultivation is the right solution for urban areas to improve air quality and support food production [25]. Structurally, the rooftop greenhouse uses mild steel as the frame and transparent plastic as the roof. Terefore, the entire plant is well-shaded to create a humid microclimate in the crop area. Rooftop pagoda mustard gardening is anticipated to generate high-quality plants. System. Water and nutrients in a hydroponic system can be carried out simultaneously using the principle of a self-fertigation system. Te visualization is given in Figure 2. A plant tub is made of wood covered with a waterproof tarp with dimensions of 150 × 150 × 25 cm (l x w x h). Tis technique is comparable to foating raft hydroponics, with the primary distinction in the absence of circulating fertigation. In foating raft hydroponic, Styrofoam is used as a bufer to keep plants afoat on the nutrient solution. Tis self-fertigation system has 100 net pots with a diameter of 5 cm. However, this study only used 50 net pots due to the extensive pagoda mustard biomass consideration. Water and nutrients should always remain stagnant during the cultivation process in the planting tub. Tey were supplied with precision by a 50 L capacity reservoir supporting a vital component known as a smart valve.

Self-Fertigation
A smart valve is a fertigation controller to set the maximum level of water and nutrients at a predetermined height. Te foat can move up and down following the water level in a tub. It opens and closes automatically based on the agreed initial setting. Furthermore, smart valves do not require electricity (zero electricity). Instead of using electrical energy, the smart valve is designed to follow the Archimedes principle. A buoyant force or upward thrust is applied to an object when partially or completely submerged in a fuid. Terefore, the construction size of each component should be calculated correctly. Te smart valve can be seen in Figure 3, with each layer from top to bottom containing an input chamber, a sponge, and an output chamber.
Te smart valve contains a sponge with dimensions of 6 cm in diameter and 4 cm in height for the automatic flling of water and nutrients. Tis implies that the nutrient reservoir will open automatically when the level in the planting tub is <6 cm and close at 6 cm. Tis sponge weighs less than the density of the liquid, hence the liquid exerts a buoyant force on it to a height of 6 cm. Te smart valve works based on water pressure from the bottom, pressing up to close the fow of nutrients from the reservoir.

Observation Sample.
Te observation sample is calculated using the Slovin formula. Tis calculates the minimum sample size when the behavior of a population is not known with certainty. It is commonly used for survey research where the sample usually has a large size. Consequently, a formula is necessary to obtain a small sample representing the complete population. Te number of samples using the Slovin approach can be calculated using equation (1), where n is the number of samples observed, N is the total population (50 net pots), and e is the error tolerance limit with a value of 10%.
Based on the calculations, the minimum number of samples observed was 33. Tis was taken based on probability and simple random sampling techniques. Each population of mustard had an equal chance of being randomly selected to represent each row and column. Figure 4 depicts the 33 samples of pagoda mustard that were analyzed.

Measurement.
Measurements on applying a selfwatering system for pagoda mustard are divided into microclimate, fertigation, and growth and yield. Each observation contains various measurement parameters to evaluate the performance of the proposed system. Te procedure for each observation is discussed in detail below: 2.5.1. Microclimate. Each measure should be precisely monitored as an evaluation indicator because the climatic conditions on the rooftop alter all the time. Te parameters consisted of temperature, relative humidity (RH), light intensity, and wind speed. Microclimate measurements on the rooftop were recorded at 7.00, 12.00, and 17.00 daily during the pagoda mustard planting period. Calibrated instruments were used to provide accurate results, including a thermohygrometer for temperature and humidity, a lux meter for light intensity, and an anemometer for wind speed. Te measuring instrument was placed in the appropriate location, and the result was displayed on the screen.

Fertigation.
Fertigation measurement includes evaluation of irrigation and nutrient during pagoda mustard cultivation, as discussed below: (1) Irrigation. Water consumption (W c ) is the amount of water used by plants. Tis is illustrated as the diference between the volume in the previous reservoir (V) and after it (V ′ ). Water consumption can be calculated using equation (2). Furthermore, the water consumption of each plant on the n-th day after planting can be calculated by dividing the total consumption by the number of plants.  Te Scientifc World Journal Te next irrigation parameter is reference evapotranspiration calculated using the Penman-Monteith method [26]. Tis method requires some data, including temperature, humidity, duration of wind and sunlight, or available radiation. Te Penman-Monteith method is recommended compared to others for the most satisfactory results [27]. In this study, the reference evapotranspiration value can be obtained using the CROPWRAT 8 software [28]. Te Penman-Monteith method has the following equation: Te ET o is the reference evapotranspiration (mm/day), Crop evapotranspiration (ET c ) is a parameter of water demand directly infuenced by plant factors. It is related to crop water requirements, calculated based on the water consumption ratio on day-n to net pot area (a). Crop evapotranspiration can be calculated using Equation (4). Water requirements are afected by evapotranspiration and crop coefcient. Plants have diferent daily coefcients depending on the reference and crop evapotranspiration values [29]. Te ratio is known as the crop coefcient parameter (K c ) (Equation (5)).
(2) Nutrient. Nutrient measurement parameters include solution temperature, electrical conductivity (EC), the potential of hydrogen (pH), and dissolved oxygen (DO). Tese measurements are recorded three times each day at 07.00, 12.00, and 17.00. Tis study executed temperature and EC parameters using the EC meter. Meanwhile, the parameters of pH and DO were measured using a pH and DO meter. Using these portable tools is very easy, and the operator only needs to dip the sensor probe into the nutrient solution to display the result on the screen. In addition, the requirement for nutrient solution during cultivation is determined based on changes in the reservoir's height.

Growth and Yield.
Measurement of growth and yield includes height, the width of biomass, root length, and biomass weight in pagoda mustard. Te procedure for each  parameter is described as follows: frstly, the height and width parameters measurement was conducted daily during plant cultivation until harvest using a ruler. Te height measurement point started from the stem base in contact with the net pot to the highest leaf tip of pagoda mustard. Meanwhile, the width of the biomass was measured from the midpoint of the mustard greens to the farthest outer diameter. Secondly, root length and biomass weight parameters were measured at harvest (40 days after planting). Te instruments used for measuring root length and weight were the rulers and analytical balance. Finally, biomass weight measurement was carried out directly after harvesting on a wet basis.

Data Analysis and Statistics.
Te performance of the self-fertigation system on the mustard pagoda was assessed using uniformity analysis to evaluate irrigation parameters, growth, biomass weight, and root length. Te uniformity analysis metrics led to the success rate of an observation based on the percentage of uniformity coefcient (UC) values [31]. Te higher the UC value, the better the performance of the self-fertigation system is [30]. Table 1 shows the UC value requirements based on uniformity analysis.

Te Limitation of Study.
Tis study focuses solely on the performance of the self-fertigation system in terms of microclimate, fertigation, and plant growth and yield. Te proposed hydroponic kit was evaluated on a rooftop greenhouse during the rainy season in Indonesia's tropical climate. Tis evaluation is conducted from the period the plants are transplanted until harvest at 40 days. Te results of this study are still limited to pagoda mustard cultivation. Te value of microclimate, fertigation, and growth and yield may difer in other commodities because each plant has unique characteristics.

Te Microclimate of a Rooftop Greenhouse.
A study was conducted to examine the potential of hydroponic kit-based growing on the self-fertigation system. Pagoda mustard is grown on rooftops in a greenhouse to provide a high-quality product. Several microclimate parameters are monitored over time to ensure that these conditions are suitable for plant growth. Figure 5 depicts the overall temperature, relative humidity (RH), light intensity, and wind speed during mustard pagoda cultivation. Firstly, environmental temperature is essential in plant growth [31]. Te inappropriateness can lead to morphological and physiological problems, where each plant has a unique environmental temperature range. Based on the analysis, the minimum and maximum temperatures in the rooftop greenhouse are 23-30.4°C. Te temperature fuctuates every time, with an average of 26.87°C, and the maximum peak occurs 26 days after planting. Te greenhouse temperature is directly proportional to plant transpiration. For example, the optimal temperature for pagoda mustard is 20-28°C. Mustard may adapt to extreme temperatures by consuming extra water and nutrients. Te greenhouse temperature is directly proportional to the absorption of water and nutrients in plants.
Secondly, RH is a crucial factor in a greenhouse, defned as the proportion of atmospheric water vapor to the same temperature. It can vary according to the ambient temperature. Based on the analysis, the rooftop greenhouse has RH between 28.67 and 74.33% and an average value of 50.32%. Te optimal for hydroponic cultivation is 70%. Furthermore, temperature and RH have an inverse relationship [32]. High RH can reduce the root's ability to absorb the nutrient solution.
Tirdly, plant growth is infuenced by sunlight consisting of light intensity, quality (wavelength), and duration of irradiation (day length). It afects the opening of stomata, formation through chlorophyll and anthocyanins, absorption of nutrients, changes in leaf and stem temperature, transpiration, the permeability of cell walls, and protoplasm movement [33]. In this study, the intensity of sunlight in the greenhouse ranged from 4,686.67 to 25,584.0 lux, with an average of 12,969.6 lux. Te light intensity is sufcient for the pagoda mustard because the greenhouse is located on the rooftop. In addition, it helps the plant to produce food from photosynthesis by absorbing water and carbon dioxide [34].
Plants can absorb visible light in photosynthesis, known as photosynthetic activity radiation (PAR) [35]. PAR is part of the solar radiation in the 400 to 700 nm wavelength range. It can be expressed in photosynthetic photon fux density (PPFD) as the amount of PAR of the light source in one unit of time [36]. Te wavelength is used to quantify the intensity of sunlight, hence the bigger the PPFD, the greater the energy of each wavelength.
Lastly, wind speed is a microclimate factor afecting plant dryness and evapotranspiration. Plants can be harmed by excessive wind speed, yet it can be assisted by providing carbon dioxide. Based on the analysis, the greenhouse's minimum and maximum wind speeds are 0.5 and 2.1 m/s, respectively. Te average wind speed is 1.13 m/s, and during the day, it is higher than in the morning and evening. Te wind speed is directly proportional to evapotranspiration, thereby increasing water requirements for plants. Conversely, the wind that brings drier air will increase plants' transpiration [37].

Irrigation.
Water consumption is the amount of water needed by plants in one planting period. It can be calculated based on the decrease in the reservoir before and after one planting period. Figure 6 depicts the amount of water consumed during mustard pagoda cultivation. Based on the   analysis, the total water consumption during one planting period was 183.73 L (equal to 0.092 L/plant day −1 ). Te trend chart visually illustrates that pagoda mustards demand much water as they reach maturity and less when ready to be harvested ( Figure 6). Te extreme consumption occurred on day 36 after planting. Tis is related to microclimatic conditions that may not suit the mustard growth.
Plant water requirement is the amount of water absorbed. It is infuenced by evapotranspiration, plant growth phase, climatic factors, and plant types [16]. Reference evapotranspiration is the rate of evaporation in the microclimate. Terefore, the site selection for plant cultivation can determine the portion of water needed. Te reference and crop evapotranspiration with crop coefcients was calculated on the consumption data. Te reference and crop evapotranspiration can be seen in Figure 7.
Te reference and crop evapotranspiration values have an increasing and decreasing trend every day respectively, leading to high and low water demand. Te reference and crop evapotranspiration ranges from 2.86 to 8.8 mm/day and 3.93 to 134.49 mm/day. Te 17 and 13 days after planting are the maximum peaks of reference and crop evapotranspiration, respectively. Evapotranspiration fuctuates greatly throughout the period due to the infuence of various factors, including sunlight, temperature, RH, and wind speed. In general, reference evapotranspiration increases with these factors. Both reference and crop evapotranspiration are important parameters for calculating crop efciency.
Another irrigation observation is the crop coefcient. Tis parameter can be infuenced by climate, evaporation, plant type, and growth phase. For example, the K c value for mustard is divided into the initial, development, midseason, and late-season stages for 17, 30, 35, and 45 days. During the initial phase, evapotranspiration is mainly in the form of soil evaporation [38]. Figure 8 depicts the actual crop coefcient values of pagoda mustard production's. Based on this fgure, the actual crop coefcient ranges from 0.01-0.54. Tis is smaller than the theoretical (0.37-1.74) issued by FAO [38]. Tis is because cultivation is conducted using a fertigation system equipped with a protector (Styrofoam and nets pot) to minimize the efect of evaporation. As a result, the proposed system can save a high amount of water consumption. Te plant growth stages consist of growing, vegetative and generative periods. Te crop coefcient value for mustard in the early, middle, and late growth periods is 0.3, 1.2, and 0.6 [38]. Annual crops require much water throughout their growth. In contrast, perennial crops require less water because they have deep roots and are more droughttolerant [39].
Te irrigation depth of the fertigation system can be seen in Figure 9. Te water depth at the location of each net pot is relatively even, and in the self-fertigation system, it is 4.2-6.8 cm, with an average of 5.88 cm. Terefore, the irrigation uniformity is 92.99% based on numerical analysis, which indicates very good criteria. Tis uniformity provides advantages, such as a good irrigation process, efective nutrients, easy seedlings, good plant growth, and uniform harvest.

Nutrient.
Nutrient is the most vital factor in supporting good quality and yields. Terefore, providing nutrients that follow plant needs can achieve optimal growth and yield. Based on the analysis, the nutrient solution needed during mustard pagoda cultivation is 2.92 L (equal to 0.0015 L/plant day −1 ). Tus, fertigation consumption is 186 L (equal to 0.0935 L/plant day −1 ). Pada nutrient, this observation contains nutrient solution temperature, EC, pH, and DO parameters. Tese parameters will be discussed in detail in Figure 10.
Plants require optimal temperatures for growth and development. Te recommended nutrient temperature for hydroponic plants is 18°C to 28°C. Tis study confrmed that the average nutrient temperature in the self-fertigation system was 27.19°C, with the minimum and maximum Te Scientifc World Journal limits between 24.7 and 29.13°C, respectively. Based on these results, the nutrient temperature is still within safe limits to provide good plant growth. It is closely related to ambient temperature, which transfers heat from the nutrient solution. Plant development is impeded, and chemical processes are accelerated when the temperature of the nutrient is too high, leading plant physiological systems to be disrupted. Furthermore, increasing the temperature of the nutrient solution might reduce oxygen levels, limiting the roots' ability to absorb nutrients. Plants have more time to create cells, tissues, and organs when the nutrient temperature is low because chemical reactions take longer.
Te next evaluation parameter on nutrient quality is EC. Based on the analysis, the self-fertigation system has an EC range between 1.86 and 2.56 μS cm −1 with an average of 2.22 μS cm −1 . A good value for pagoda mustard is 1.6-2.5 μS cm −1 . As shown in Figure 10, EC experienced an increasing trend from 10 days after planting until harvest. Park and Cho [40] explained that changes infuenced the trend in nutrient temperature, where the EC was inversely proportional to the   temperature of the nutrient. Te higher the temperature, the lower the EC, and vice versa. EC is closely related to the concentration of ions in the water, absorbed by the roots later. Terefore, the plant will absorb more nutrients when exposed to sunlight. Te stomata are opened with the element Potassium (K + ), causing the release of Hydrogen (H + ) for the nutrient absorption process [41].
Te next nutrient parameter is pH. Pagoda mustard has an optimal pH between 5.5 and 6.5. Based on observations, the self-fertigation system applied has an average pH of 6.34 for plant growth. However, some observations showed the pH was more than 6.5. Tis is caused by the high pH of the initial source of raw water. Terefore, 10% nitric acid (HNO 3 ) was used to overcome this, and the pH in subsequent observations was under the criteria.
Te last parameter in nutrients is DO. In cultivating aquatic culture plants, the area adjacent to the air has a higher DO and vice versa. Tis is because every plant cell needs oxygen to carry out respiration, whereas the roots will need the energy to absorb water and nutrients. Te plant will die when its respiration is insufcient, and water and nutrients will no longer be absorbed. Terefore, adequate oxygen levels will improve the performance of the root in the speed of absorption of water and nutrients.
A root-in-water hydroponic system or water culture necessitates a DO range between 4 and 10 mg L −1 . Te nutrient solution in the hydroponic system is considered very good if the dissolved oxygen content is 8 mg L −1 . Based on the measurements, the DO of nutrients in the selffertigation system ranges from 4.1 to 7.9 mg L −1 and an average of 6.21 mg L −1 . Tis confrms that the DO complies with the general recommendations that have been set for hydroponics.

Growth and Yield of the Mustard Pagoda.
Te performance of the self-fertigation system was evaluated based on morphological measurements of the mustard pagoda. Te parameters include height, the width of biomass, root length, and biomass weight. In this study, the pagoda mustard was measured in the vegetative stage. Terefore, morphological measurements were plant height and diameter. Tis is a morphological measurement technique to complete the mustard pagoda data's growth and yield, as shown in Figure 11. Figure 12 depicts the height and width of the pagoda mustard plant biomass. Tese parameters are growth indicators that are often observed to analyze the treatment response [42]. Based on the analysis, the average height and width of the pagoda mustard were 22.88 and 26.42 cm, respectively. In addition, the uniformity value for plant height and width was 80.07% and 84.07%. Tis implies that applying a self-fertigation system has good growth and development impact on pagoda mustard.
Leaf biomass is a plant vegetative organ with an essential role in photosynthesis. Te biomass width afects the amount of sunlight needed for this process. Meanwhile, the biomass area is directly proportional to the amount of sunlight received. Nutrients are very infuential in biomass formation, especially the element N, which plays a role in constructing shoots, leaves, and stems. A sufcient amount of N will impact the expansion of the leaf surface and lead to good yields [43].
Several samples of pagoda mustard were harvested for yield measurement 40 days after planting. Tis measurement is derived from the plant growth process, where efcient photosynthesis produces optimal yields. Plant roots are one of the success factors for good growth because they are in direct contact with water and nutrient solutions. Based on the analysis, pagoda mustard has an average root length of 23.64 cm with a minimum and maximum length of 14.5 and 43 cm, respectively ( Figure 13). Visually, the seed is white and has a straight and thick shape. Adequate oxygen levels regulate this to maintain its circulation in the water. Factors that afect the root distribution pattern include temperature, aeration, availability of water, and nutrients [41]. Terefore, good root growth will have an impact on increasing harvest weight.
Based on the analysis, pagoda mustard has an average plant weight of 241.5 g with a minimum and maximum value of 127 g and 376 g. Overall, the total product weight is 11.295 kg, with an area of 2.25 m 2 . Based on this data, land productivity in applying the self-fertigation system is 5.02 kg/m 2 . Tese results indicate that the self-fertigation system is considered suitable for mustard growth. Terefore, using a self-fertigation system can be a good solution to narrow agricultural land and increase the value of productivity. Tis research demonstrates that this system can be installed in various settings, including rooftops.

Discussion
In most metropolitan areas in developing countries, the existing system often fails to efectively meet the availability of horticultural products. Hydroponics ofers a promising solution to deal with the scarcity of leafy vegetable supply. Also, hygienic, safe, and nutritious product quality is a major challenge at all levels of rural and urban social society. In this research, self-fertigation system-based hydroponic kit technology has great potential to overcome the above issues. Tis technology claims the slogan "zero electricity" to supply the availability of horticultural products while reducing operational production costs. Based on the performance evaluation, the hydroponic kit can adapt to the surrounding microclimate circumstances to maintain safe fertigation quality. Tus, plant growth can run optimally, leading to higher productivity.
Te general factors for increasing productivity are creating suitable microclimate conditions, setting plant spacing, and availability of appropriate nutrients. In this study, the life cycle of pagoda mustard was concise compared to mustard grown traditionally on a soil-based basis in open felds, which could reach 60 days. One aspect of this accomplishment is the availability of nutrients during cultivation and directly to the root zone. In hydroponics, nutrients play an essential role in complementing the micronutrients and macronutrients. Nutrient distribution usually uses capillary action which works well for leafy vegetables, herbs, and spices. Pakpahan, HB, and Mahmudah [44] argue that the recommended concentration of nutrients for good growth of Pagoda mustard is 1400 ppm. Recently, several researchers have directed their studies in an environmentally friendly direction by using liquid organic fertilizers as alternative nutrients for hydroponics [45][46][47].
Evaporation in hydroponic farming is relatively low so this can be considered a water-saving method. Evapotranspiration as a major component of the hydrological cycle will infuence crop water requirements and future planning related to irrigation management. Based on the analysis, this hydroponic kit has an evapotranspiration reference value of 2.86 to 8.8 mm/day, which has a fairly low evaporation rate. Tis will help the user since water and nutrients can be saved. Evapotranspiration in mustard has also been reported by previous researchers with various approaches, including 2.42 mm/day with Bowen's ratio energy balance approach [48], 132.6 mm/day by using the FAO dual crop coefcient approach [49], 7.98 mm/day by applying the FAO method [50], and 5.9 mm/day with FAO method [51]. Te evapotranspiration value will correlate with the crop coefcient, representing crop and water management methods. If plants are often irrigated until harvest, the soil's surface will be wet and crop yield will be relatively high. Alternatively, the crop coefcient value will be quite low if the plants are allowed to dry on the land [49].
Growing plants with a hydroponic kit based on a selffertilization system could be an appropriate technology. We hope this technology can be applied in underdeveloped areas in various developing countries where the scarcity of electrical energy is the main obstacle. Tere is also a lot of potential for this hydroponic kit technology to be used in places with low rainfall prone to drought. Tis hydroponic testing kit is not limited to only horticultural products, but we encourage various scientists to test on foricultural commodities. Tus, the characteristics of each commodity can be known so that the readiness level of hydroponic kit technology based on the self-fertigation system can run efectively and efciently.

Conclusion
Te results demonstrated that a hydroponic kit based on a self-fertigation system has good potential to be applied to pagoda mustard production. Te proposed system can provide suitable conditions for plant growth during the cultivation process. Furthermore, the system is environmentally friendly because it requires no electricity (zero energy) throughout the cultivation of plants. Based on the analysis, pagoda mustard has the following morphological characteristics: average height of 22.88 cm, biomass width of 26.42 cm, root length of 23.4 cm, and weight of 241.5 g. Te self-fertigation system showed good performance for growth with a uniformity value between 80 and89%. Te production takes 40 days with total fertigation consumption of 186 L (equal to 0.0935 L/plant day −1 ). Terefore, hydroponic kits based on self-fertigation systems can be applied in urban and other areas without access to electricity to produce and maintain a sustainable food supply.

Data Availability
Te data used to support the fndings of this study are available from the corresponding author upon request.

Conflicts of Interest
Te authors declare that they have no conficts of interest regarding the publication of this manuscript.