iv. Obtain this resistor from the lab GTA and connect it into the network.

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1 Lab Experiment No. esistor Connections I. Introduction In this lab exercise, you will learn how to read schematic diagrams of electronic networks, how to transform schematics into actual element connections, correct ways to layout a breadboard connection of a network, how to connect the DMM for measuring, and how to combine resistors to establish terminal equivalence. II. Experiment Procedure collection of resistive networks are given in Figures through. The schematic diagram of the network is shown in (a) while the resistor connection is shown in (b) in each Figure. Obtain from the lab GT all of the resistors required for these experiments. Use these resistors to correctly layout each of these networks on your breadboard. pply the bench DMM to take measurements and make calculations required to fill out the tables provided with each network. Use specified and calculated values as the basis for percentage variations. (a) Series connection. series connection of resistors is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while the actual resistor connection is shown in Figure (b). Fill out Table with data obtained below. i. Measure the of each resistor in the series connection. ii. With the specified resistor value as the basis, calculate resistor variations in per-cent. iii. Calculate the value of the at the terminals -. This is the terminal. iv. pply the DMM to measure. v. Calculate the variation in in. (b) Parallel connection. parallel connection of resistors is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while actual resistor connection is shown in Figure (b). Fill out Table with data obtained below. i. Measure the of each resistor in the parallel connection. ii. With the specified resistor value as the basis, calculate resistor variations in per-cent. iii. Calculate the value of the at the terminals -. This is the terminal. iv. pply the DMM to measure. v. Calculate the variation in in. (c) Series/parallel combination. series connection of parallel resistors is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while the actual resistor connection is shown in Figure (b). Fill out Table with data obtained below. i. Measure the of each resistor in the connection. ii. With the specified resistor value as the basis, calculate resistor variations in per-cent. iii. Calculate the value of the resistor x that will produce a terminal of Ω. iv. Obtain this resistor from the lab GT and connect it into the network. v. pply the DMM to measure. vi. Calculate the variation in from Ω in. (d) Parallel/series combination. parallel connection of series resistors is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while the actual resistor connection is shown in Figure (b). Fill out Table with data obtained below. i. Measure the of each resistor in the connection. ii. With the specified resistor value as the basis, calculate resistor variations in per-cent. iii. Calculate the value of the resistor x that will produce a terminal of.kω. iv. Obtain this resistor from the lab GT and connect it into the network. v. pply the DMM to measure. vi. Calculate the variation in from.kω in.

2 (e) Combination (Combo ) connection. combination connection of resistors in series and parallel is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while the actual resistor connection is shown in Figures (b). Fill out Table with data obtained below. i. Measure the of each resistor in the connection. ii. With the specified resistor value as the basis, calculate the resistor variation in per-cent. iii. Calculate the value of the at the terminals -. This is the terminal. iv. pply the DMM to measure. v. Calculate the variation in in. (f) Combination (Combo ) connection. Yet another combination connection of resistors in series and parallel is shown in Figure. The schematic diagram of this connection is shown in Figure (a) while the actual resistor connection is shown in Figures (b). Fill out Table with data obtained below. i. Measure the of each resistor in the connection. ii. With the specified resistor value as the basis, calculate the resistor variation in per-cent. iii. Calculate the value of the at the terminals -. This is the terminal. iv. pply the DMM to measure. v. Calculate the variation in in. III. Lab eport The report for this lab experiment must be word-processed and contain the following items Title Page. Introduction. Procedure. esults. Discussions. (a) Suggest useful applications for the connections studied in this experiment. Conclusion. Provide detailed comments and discussions on the items listed below for each resistor network. (a) re all resistors within tolerance? List those that are not. (b) ccount for the difference between measured and calculated (that is, the calculated variation or tolerance of ). (c) Explain how the variation in corresponds to resistor tolerance. (d) Explain how close the calculated values of x in the series/parallel and parallel/series connections are to standard resistor values. Consider resistor tolerance. ppendix. eferences.

3 Series Connection.9KΩ KΩ.KΩ.KΩ.KΩ (a) (b) Figure (a) Schematic for the series connection Table Series connection esistor Specified value ( i ).9K K.K.K.K Calculated value

4 Parallel Connection 0KΩ.KΩ KΩ.KΩ.KΩ (a) Figure (a) Schematic for the parallel connection (b) Table Parallel connection esistor Specified value ( i ) 0K.K K.K.K Calculated value

5 Series/Parallel Connection Ω 0Ω Ω x Ω Ω Ω Ω x Ω 9Ω 9 9 (a) Figure (a) Schematic for the series/parallel connection (b) Table Series/parallel connection esistor Specified value ( i ) x Specified value

6 Parallel/Series Connection.0KΩ.KΩ.KΩ.KΩ x.kω x.kω.kω 9.KΩ 9.KΩ 9 (a) Figure (a) Schematic for the parallel/series connection (b) Table Parallel/series connection esistor Specified value ( i ).K.K K.K.K.K.K.K 9.K 9 x Specified value

7 .K Combo Connection 00Ω 9.KΩ.KΩ.KΩ.KΩ KΩ KΩ.KΩ 9.KΩ KΩ KΩ.KΩ.KΩ.KΩ 00Ω 0 KΩ (a) Schematic for Combo connection Figure

8 Table Combo connection esistor Specified value ( i ) 00.K.K.K.K.K.K.K.K K.K K K K K Calculated value

9 Combo connection KΩ 0KΩ 9 0KΩ 0KΩ 0KΩ 00KΩ 0KΩ 0 00KΩ KΩ 0KΩ 00KΩ 0KΩ KΩ KΩ KΩ KΩ (a) Schematic for Combo connection Figure

10 Table Combo connection esistor Specified value ( i ) K 0K 0K 0K 0K K 0K K 9 0K 0 00K 00K K 00K 0K K K Calculated value

vi. Apply 3V DC to your circuit network and measure the current through each resistor vii. Verify Kirchhoff s Current Law

vi. Apply 3V DC to your circuit network and measure the current through each resistor vii. Verify Kirchhoff s Current Law Lab Experiment No. EE1106, Fall 201 Connections I. Introduction In this lab exercise, you will learn how to read schematic diagrams of electronic networks, how to transform schematics into actual element