3.2. In a water treatment process, we use a biological process to remove biodegradableorganic matter. The organic matter is measured as the BOD, where the optimalBOD of effluent should be less than 20 mgl-. Let B represent a fuzzy set "goodeffluent" on the universe of optical BOD values (20, 40, 60) as defined by themembership function0.50.81.0604020The retention time is critical to a bioreactor; we try to find the retention time,measured in days. Let T represent a fuzzy set called optimal retention time on theuniverse of days (6, 8, 10) as given by the membership function0.90.60.4HI = 10* 8The utilization rate of organic food indicates the level of the treatment in thebiological process, and this rate is measured on a universe of fractions from 0 to 1,where 1 is optimal. Fuzzy set U will represent "high utilization rates," as definedby the membership function0,80.60.40.9 0.8 0.7 0.6We can define the following relations:R = B x T, which reflects how retention time affecets BOD removal:S=T x U, which relates how retention time affects organic food consumption;andW = Ro S, which represents the BOD removal and food utilization.(a) Find R and S using Cartesian products.(b) Find W using max-min composition.

Introduction The amount of dissolved oxygen required by aerobic biological organisms to break down…

3.2. In a water treatment process, we use a biological process to remove biodegradable organic matter. The organic matter is measured as the BOD, where the optimal BOD of effluent should be less than 20 mgl-. Let B represent a fuzzy set "good effluent" on the universe of optical BOD values (20, 40, 60) as defined by the membership function 0.5 0.8, 1.0 20 60 40 The retention time is critical to a bioreactor, we try to find the retention time, measured in days. Let T represent a fuzzy set called optimal retention time on the universe of days (6, 8, 10) as given by the membership function 0.9 0.6 0.4 The utilization rate of organic food indicates the level of the treatment in the biological process, and this rate is measured on a universe of fractions from 0 to 1, where 1 is optimal. Fuzzy set U will represent "high utilization rates." as defined by the membership function 0.8 0.6 0.4 0.9 0.8 0.7 0.6 We can define the following relations: R = Bx T. which reflects how retention time affects BOD removal; S=TxU, which relates how retention time affects organic food consumption; and W = RoS, which represents the BOD removal and food utilization. (a) Find R and S using Cartesian products. (b) Find W using max-min composition.

3.2. In a water treatment process, we use a biological process to remove biodegradable organic matter. The organic matter is measured as the BOD, where the optimal BOD of effluent should be less than 20 mgl-. Let B represent a fuzzy set "good effluent" on the universe of optical BOD values (20, 40, 60) as defined by the membership function 0.5 0.8, 1.0 20 60 40 The retention time is critical to a bioreactor, we try to find the retention time, measured in days. Let T represent a fuzzy set called optimal retention time on the universe of days (6, 8, 10) as given by the membership function 0.9 0.6 0.4 The utilization rate of organic food indicates the level of the treatment in the biological process, and this rate is measured on a universe of fractions from 0 to 1, where 1 is optimal. Fuzzy set U will represent "high utilization rates." as defined by the membership function 0.8 0.6 0.4 0.9 0.8 0.7 0.6 We can define the following relations: R = Bx T. which reflects how retention time affects BOD removal; S=TxU, which relates how retention time affects organic food consumption; and W = RoS, which represents the BOD removal and food utilization. (a) Find R and S using Cartesian products. (b) Find W using max-min composition.

Aquaculture Science

3rd Edition

ISBN:9781133558347

Author:Parker

Publisher:Parker

Chapter11: Health Of Aquatic Animals

Section: Chapter Questions

Problem 3KA

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