Hey, sorry this took so long to post but I had a project that needed to get done for school. Hopefully you'll respond! Anyway,
Summing the voltages in the loop you get:
[tex]5000i+10000i=3\rightarrow15000i=3 \rightarrow i=\frac {3}{15000} =.0002 A=.2 mA=200 \mu A[/tex]
voltage drop across the 5k resistor:
[tex]5000 \Omega * .0002A= 1v[/tex]
so voltage at the terminal is 2v, which is correct according the answer sheet so then to find Vo we can use the fact that the current through the 2k resistor is the same as the current through the 8k resistor like so:
[tex]i_{1}=i_{2}[/tex]
[tex]\frac {V_{s}-V_{1}}{R_{1}} = \frac {V_{1}-V_{0}}{R_{f}}[/tex]
now solve this for Vo:
[tex]R_{f}(V_{s}-V_{1})=R_{1}(V_{1}-V_{0})[/tex]
[tex]\frac {R_{f}}{R_{1}} (V_{s}-V_{1})= (V_{1}-V_{0})[/tex]
[tex]-V_{0} = \frac {R_{f}}{R_{1}} (V_{s}-V_{1}) - V_{1}[/tex]
[tex]V_{0} = -\frac {R_{f}}{R_{1}} (V_{s}-V_{1}) + V_{1}[/tex]
[tex]V_{0} = -\frac {8}{2} (1) + 2 = -4+2 = -2v[/tex]
this is also correct. Now I need to find Io and if we apply KCL to the node where Io points we should get:
[tex]i_{0} = \frac {V_{0}}{8000}+\frac {V_{0}}{4000} = \frac {-2}{8000}+\frac {-2}{4000} = -.00075 A = -.75mA=-750 \mu A[/tex]
the answer is suppose to be -1mA which you could round to from -.75mA but since the other answers came out exactly this seems wrong to me. Can I get a little more help?