ip.hb	=1.05457.E-34	%J*s	%reduced Planck constant	mif,aos,ioo
ip.c	=2.99792458.E+08	%m/s	%speed of light	mif,aos,ioo,las
ip.kb	=1.38.E-23	%J/K	%Boltzmann's constant	cry,vis,vac,mir
ip.g	=9.8.E+00	%m/s^2	%acceleration of gravity	mif,vis,cry,vac,aos,mir
ip.lambda	=1.064.E-06	%m	%wavelength	mif,aos,ioo,las,cry,vac,mir
ip.rho_sap	=4.0.E+03	%kg/m^3	%density of Sapphire	mir,cry,vis
ip.Y_sap	=4.0.E+11	%Pa	%Young's modulus of Sapphire	mir,cry,vis
ip.sigma_sap	=2.9.E-01	%	%Poisson ratio of Sapphire	mir,cry,vis
ip.alpha_sap	=5.6.E-09	%1/K	%thermal expansion of Sapphire at 20K	mir,cry
ip.Cs_sap	=6.9.E-01	%J/kg/K	%specific heat of Sapphire	mir,cry
ip.kappa_sap	=1.57.E+04	%W/m/K	%thermal conductivity of Sapphire	mir,cry
ip.n_sap	=1.754.E+00	%	%refractive index of Sapphire	mir,mif,aos,vac
ip.tensile_sap	="=TBD"	%Pa	%tensile strength of Sapphire fiber	cry,vis
ip.rho_sil	=2.2.E+03	%kg/m^3	%density of Silica	mir,vis
ip.Y_sil	=7.2.E+10	%Pa	%Young's modulus of Silica	mir,vis,mif
ip.sigma_sil	=1.7.E-01	%	%Poisson ratio of Silica	mir
ip.alpha_sil	=5.1.E-07	%1/K	%thermal expansion of Silica at 290K	mir
ip.Cs_sil	=1.64.E+06	%J/m^3/K	%specific heat of Silica	mir
ip.kappa_sil	=1.38.E+00	%W/m/K	%thermal conductivity of Silica	mir
ip.n_sil	=1.45.E+00	%	%refractive index of Silica	mir,mif,aos,vac
ip.Y_tan	=1.4.E+11	%Pa	%Young's modulus of Tantala	mir,vis,mif
ip.sigma_tan	=2.3.E-01	%	%Poisson ratio of Tantala	mir
ip.alpha_tan	=3.6.E-06	%1/K	%thermal expansion of Tantala at 290K	mir
ip.Cs_tan	=2.1.E+06	%J/m^3/K	%specific heat of Tantala	mir
ip.kappa_tan	=3.3.E+01	%W/m/K	%thermal conductivity of Tantala	mir
ip.n_tan	=2.07.E+00	%	%refractive index of Tantala	mir,mif,aos,vac
ip.rho_Cu	=8.93.E+03	%kg/m^3	%density of Copper	cry,vis
ip.Y_Cu	=1.298.E+11	%Pa	%Young's modulus of Copper	cry,vis
ip.sigma_Cu	=3.43.E-01	%	%Poisson ratio of Copper	cry,vis
ip.alpha_Cu	="=TBD"	%1/K	%thermal expansion of Copper at 20K	cry
ip.Cs_Cu	="=TBD"	%J/kg/K	%specific heat of Copper at 20K	cry
ip.kappa_Cu	="=TBD"	%W/m/K	%thermal conductivity of Copper at 20K	cry
ip.RRR_Cu	=2.0.E+01	%	%RRR of Copper	cry
ip.tensile_Cu	="=TBD"	%Pa	%tensile strength of Cu fiber	cry,vis
ip.rho_Al	=2.69.E+03	%kg/m^3	%density of Aluminum	cry,vis
ip.Y_Al	=7.03.E+11	%Pa	%Young's modulus of Aluminum	cry,vis
ip.sigma_Al	=3.45.E-01	%	%Poisson ratio of Aluminum	cry,vis
ip.alpha_Al	="=TBD"	%1/K	%thermal expansion of Aluminum at 20K	cry
ip.Cs_Al	="=TBD"	%J/kg/K	%specific heat of Aluminum at 20K	cry
ip.kappa_Al	="=TBD"	%W/m/K	%thermal conductivity of Aluminum at 20K	cry
ip.RRR_Al	=4.0.E+03	%	%RRR of Aluminum	cry
ip.tensile_Al	="=TBD"	%Pa	%tensile strength of Al fiber	cry,vis
ip.rho_bol	=7.60.E+03	%kg/m^3	%density of Bolfur	cry,vis
ip.Y_bol	=1.568.E+11	%Pa	%Young's modulus of Bolfur	cry,vis
ip.sigma_bol	="=TBD"	%	%Poisson ratio of Bolfur	cry,vis
ip.alpha_bol	="=TBD"	%1/K	%thermal expansion of Bolfur	cry
ip.Cs_bol	="=TBD"	%J/kg/K	%specific heat of Bolfur	cry
ip.kappa_bol	="=TBD"	%W/m/K	%thermal conductivity of Bolfur	cry
ip.RRR_bol	="=TBD"	%	%RRR of Bolfur	cry
ip.tensile_bol	=3.528.E+09	%Pa	%tensile strength of 100um Bolfur fiber	cry,vis
ip.bigG	=6.673.E-11	%m^3/kg/s^2	%Gravitational constant	das
ip.ms	=1.989.E+30	%kg	%solar mass	das
ip.neutron	=1.4.E+00	%solar mass	%neutron star mass	das
ip.fmax	=1.570.E+00	%Hz	%end freq of BNS inspiral	das
ip.snr	=8.0.E+00	%	%SNR for IR calculation	das