Susan Windsor - Critical Thinking for Testers - EuroSTAR 2010TEST Huddle
EuroSTAR Software Testing Conference 2010 presentation onCritical Thinking for Testers by Susan Windsor. See more at: http://conference.eurostarsoftwaretesting.com/past-presentations/
Granted planning consent in January 2011, this project will shortly be 'aired' for exhibition - to offer local employment opportunities, training & educational facilities - to teach people what is (& what is NOT) sustainable.
Peter Zimmerer - Passion For Testing, By Examples - EuroSTAR 2010TEST Huddle
EuroSTAR Software Testing Conference 2010 presentation on Passion For Testing, By Examples by Peter Zimmerer. See more at: http://conference.eurostarsoftwaretesting.com/past-presentations/
Susan Windsor - Critical Thinking for Testers - EuroSTAR 2010TEST Huddle
EuroSTAR Software Testing Conference 2010 presentation onCritical Thinking for Testers by Susan Windsor. See more at: http://conference.eurostarsoftwaretesting.com/past-presentations/
Granted planning consent in January 2011, this project will shortly be 'aired' for exhibition - to offer local employment opportunities, training & educational facilities - to teach people what is (& what is NOT) sustainable.
Peter Zimmerer - Passion For Testing, By Examples - EuroSTAR 2010TEST Huddle
EuroSTAR Software Testing Conference 2010 presentation on Passion For Testing, By Examples by Peter Zimmerer. See more at: http://conference.eurostarsoftwaretesting.com/past-presentations/
Presented in this short document is a description of how to model and solve multi-utility scheduling optimization (MUSO) problems in IMPL. Multi-utility systems (co/tri-generation) are typically found in petroleum refineries and petrochemical plants (multi-commodity systems) especially when fuel-gas (i.e., off-gases of methane and ethane) is a co- or by-product of the production from which multi-pressure heating-, motive- and process-steam are generated on-site. Other utilities include hydrogen, electricity, water, cooling media, air, nitrogen, chemicals, etc. where a multi-utility system is shown in Figure 1 with an intermediate or integrated utility (both produced and consumed) such as fuel-gas, steam or electricity. Itemized benefit areas just for better management of an integrated steam network can be found in Pelham (2013) where his sample multi-pressure steam utility flowsheet is found in Figure 2.
Presented in this short document is a description of how to model and solve multi-utility scheduling optimization (MUSO) problems in IMPL. Multi-utility systems (co/tri-generation) are typically found in petroleum refineries and petrochemical plants (multi-commodity systems) especially when fuel-gas (i.e., off-gases of methane and ethane) is a co- or by-product of the production from which multi-pressure heating-, motive- and process-steam are generated on-site. Other utilities include hydrogen, electricity, water, cooling media, air, nitrogen, chemicals, etc. where a multi-utility system is shown in Figure 1 with an intermediate or integrated utility (both produced and consumed) such as fuel-gas, steam or electricity. Itemized benefit areas just for better management of an integrated steam network can be found in Pelham (2013) where his sample multi-pressure steam utility flowsheet is found in Figure 2.