1. Considering the case study mentioned above, apply network theorem to determine the power delivered at load and lost to the internal resistance of the supplies. 2. Determine the load for maximum power transfer condition for each of the power supplies and connecting them all in parallel. 3. If you have control over the internal resistance, then determine the value of internal resistance for Maximum power to the load.

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Three different types of DC sources are available (Fig-1 below), and all are connected in parallel, (a) 12V
IPS battery, (b) a 12V dry cell and (b) 12V DC supply from laboratory.
Now each of the supply has an internal resistance of '4', '9' and '2' (respectively). Now, a load of '18'0
is connected to the end of the combined parallel supply. (Anyvaluecomes '0'need to consider '9' for your
assignment)
Rint
+
E
12 V
Rint
E
Rint
12V E
12 V
RL
(a)IPS battery (b) Dry cell (c)Laboratory supply
Fig-1
1.
2.
3.
If you have control over the internal resistance, then determine the value of internal resistance for
Maximum power to the load.
4. If a capacitor ('eb' µF) is connected series with the load at maximum power transfer, then sketch the
behavior of the transient response of the system when connecting all power supplies parallel
with load.
5. Show all the circuit configurations in simulation along with output/responses
Considering the case study mentioned above, apply network theorem to determine the power
delivered at load and lost to the internal resistance of the supplies.
Determine the load for maximum power transfer condition for each of the power supplies and
connecting them all in parallel.
Transcribed Image Text:Three different types of DC sources are available (Fig-1 below), and all are connected in parallel, (a) 12V IPS battery, (b) a 12V dry cell and (b) 12V DC supply from laboratory. Now each of the supply has an internal resistance of '4', '9' and '2' (respectively). Now, a load of '18'0 is connected to the end of the combined parallel supply. (Anyvaluecomes '0'need to consider '9' for your assignment) Rint + E 12 V Rint E Rint 12V E 12 V RL (a)IPS battery (b) Dry cell (c)Laboratory supply Fig-1 1. 2. 3. If you have control over the internal resistance, then determine the value of internal resistance for Maximum power to the load. 4. If a capacitor ('eb' µF) is connected series with the load at maximum power transfer, then sketch the behavior of the transient response of the system when connecting all power supplies parallel with load. 5. Show all the circuit configurations in simulation along with output/responses Considering the case study mentioned above, apply network theorem to determine the power delivered at load and lost to the internal resistance of the supplies. Determine the load for maximum power transfer condition for each of the power supplies and connecting them all in parallel.
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