I need Healp with this lab

just need this data table to be filled in, please

R1-33, R2-99, R3-315

Lab-9 (LK) Combination of Series and Parallel Circuit The names of each spring connector in the circuit board are shown in Figure 2. In the rectangular areas of Figure 2, the springs are connected in pairs, oriented perpendicular to each other Objective and named C and S. In a given rectangular area, the two springs should be treated equally in circuit connection. For example, connecting to Cl means connecting to $1 also. Therefore the names Cl 1. Learn to build up a combination of series and parallel circuit with three resistors and one DC and $1 are interchangeable in the following circuit build procedures. Similarly for C2 and $2. source. 2. Measure current passing through each resistor, and measure the voltage across each resistor. 3. Verify the equations of the combination of series and parallel circuit. Pushbutton LCI KIT NO switch Equipment LC2 1 EM-8656 AD/DC Electronics Lab Component 2 PS-3211 Wireless voltage sensor aVOLTS MAX spring 3 PS-3212 Wireless current sensor Battery Holder 4 SE-8829 Student Multimeter 5 2 Batteries 6 Wires and Resistors (A) $2 RZ R3 R 33 0 100 0 320 0 C1 Banana Jacks CS Theory Circuits combined by series and parallel wirings can be reduced into one equivalent resistance step by step. Each step is purely a series or parallel circuit. The circuit in the Figure 1 can be reduced into AS scientific EM-1656 ACDC ELECTRONICS LABORATORY one equivalent resistance through two steps: R, and Ry locally parallel equivalent to Rza; then, R, and R23 locally series equivalent to Riotal- The resistance, current, and voltage relations for three resistors the Figure 2: definition of the names of each spring connector circuit are the following: Procedure A: Build a circuit as shown in Figure 1 using Pasco AD/DC Electronics Lab. R2 1 1 1 (1) 1. Check Battery and put two batteries into the Battery Holder. Use the multimeter to check the values 123 = 12 + la (2) of each battery (battery-1 across B1 and B2; and battery-2 across B3 and B4). The value of each AV23 = AV2 = AV, (3 ) battery should be close to 1.5V. The B2 wire should connect to B3 (two batteries connected together), and record the DC voltage between B1 and B4 in the Table. 2. Build a series circuit AVtotal Rtotal = R1 + R23 ( 4 ) 2.01 B4 wire connects to J4 Itotal = 1 = 123 ( 5 ) 2.02 B1 wire connects to J8 AVtotal = AV] + AV23 (6) 2.03 C4 wire connects to C3 CA Figure 1 2.04 C3 wire connects to C2 2.05 C3 wire connects to C1 R2 Procedures 2.06 $7 R, connects to $8 2.07 $2 R2 connects to $6 A. Build a parallel circuit as shown in Figure 1 using Pasco AD/DC Electronics Lab. C5 C6 C7 K1 B. Capstone Software and checking the circuit connection. 2.08 $1 R3 connects to $5 c. Data collection and calculations 2.09 C5 wire connects to C6 2.10 C6 wire connects to C7 Using Pasco AD/DC Electronics Lab to build circuits: Figure 3: Circuit connections on the circuit Board.Procedure B: Capstone Software and checking the circuit connection. 1.4 Use your camera to take an image of your measurement setup. The image should show the 1 Check whether the total number of wires and resistors in your circuit is 10. If it is not, please check voltage and current sensors, which have the Bluetooth ID. Submit the image during the lab time. procedure A2 (the wire between B2 and B3 does not count). 2 Use the multimeter's "voltage function" to measure the voltage across J4 and J8. Record this value 2. Data collection (for R,) (4V] in the table. 2.1 Remove the current sensor and the voltage sensor from the circuit. Disconnect C4 and C3 (remove the wire between C4 and C3). Use the multimeter's "resistance 2.2 Reconnect C4 and C3 by a wire. function" to measure the total resistance between $3 and $8, record this value (Rtotal) in the table 2.3 Disconnect the wire between Co and C7. 4 Verify equation (4). If your data does not match equation (4), please check Procedure-A2 2.4 Insert current sensor between $6 and $7, the sensor will give the current (1,) passing resistor R1. connections. Do not move to the next steps until the verification of equation (4) is passed. The current also equal to /23- 5 Insert current sensor between $4 and $3, the sensor will give the current (total) passing all the 2.5 Parallel connect voltage sensor across R, (across $7 and $8), the sensor will give the voltage resistors Rtotal- (4V,) across resistor R1- Parallel connect voltage sensor across $4 and $8, the sensor will gives the voltage (AVital) across 2.6 Open a new page on the Capstone, and open a table, name the "Table title" as "RI data". all the resistors Rtotal- 2.7 Click the 'RECORD' button. Wait about one second, click the button again to stop recording. 7 Capstone Software and Sensors: Input the current and voltage average values in the data table. 7.1 Turn on the Capstone software. Press the power button on the wireless voltage sensor and 3. Data collection (for R2) wireless current sensor. The red LED should start blinking. The voltage/current sensor is now ready 3.1 Remove the current sensor and the voltage sensor from the circuit. to connect via Bluetooth. 3.2 Reconnect C6 and C7 by a wire. 7.2 In the "Tools Palette" (on left side of screen) click on "Hardware Setup". This will open the hardware palette. Select the Bluetooth symbol. You should see the voltage/current sensor that 3.3 Disconnect the wire between C2 and C3. is visible to Bluetooth to the computer. Select the sensor. Make sure its ID is the same as on the 3.4 Insert current sensor between $3 and $2, the sensor will give the current (12) passing resistor Ry. sensor. 3.5 Parallel connect voltage sensor across Ry (across $2 and $6), the sensor will gives the voltage 7.3 Click "Hardware Setup" once again. This will close the hardware palette. AV,] across resistor R2- 7.4 As the hardware palette closes, the display palette opens up. Double click the "Table" on the 3.6 Open a new page on the Capstone, and open a table, name the "Table title" as "R2 data". up-right corner to open a table with two columns. On the left column of the table page, set 3.7 Click the 'RECORD' button. Wait about one second, click the button again to stop recording. the "Select Measurement" as current; and on the right column of the table page, set the Input the current and voltage average values in the data table. "Select Measurement" as voltage. Data collection (for R3) 7.5 At the bottom-lower left of the screen is the 'RECORD' button. Once you click it, the system will start recording the current and voltage on the Table page. It will stop recording when clicked 4.1 Remove the current sensor and the voltage sensor from the circuit. a second time. Click the "E" icon to get the current and voltage average (mean) values. 4.2 Reconnect C2 and C3 by a wire. 4.3 Disconnect the wire between C5 and C6. Procedure C: Data collection and calculations 4.4 Insert current sensor between $5 and $6, the sensor will give the current (Is) passing resistor Ra. 1. Data collection (for Rtotal) 4.5 Parallel connect voltage sensor across Ra (across $1 and $5), the sensor will give the voltage 1.1 Refer to Procedure B step 5 and 6, click the 'RECORD' button. Wait about one second, click (4V,] across resistor Ra- the button again to stop recording. 4.6 Open a new page on the Capstone, and open a table, name the "Table title" as "R3 data". 1.2 Input the current and voltage average values in the data table. 4.7 Click the 'RECORD' button. Wait about one second, click the button again to stop recording. 1.3 On the Capstone table page, enter the "Table title here" as "R-total data". Take a screenshot Input the current and voltage average values in the data table. of the Capstone data table, and submit it during the lab time. 5. Data collection (for R23) 5.1 Remove the current sensor and the voltage sensor from the circuit.5.2 ReconnecT C5 and C6. 5.3 Refer To sTep 2.4 for currenT (123). 5.4 Parallel connecT volTage sensor across 82 and 86, The sensor will give The volTage [AI/23) across equivalenT resisTor R23. 5.5 Open a new page on The CapsTone, and open a Table, name The "Table TiTle\" as "R23 daTa". 5.6 Click The 'RECORD' buTTon. WaiT abouT one second, click The buTTon again To sTop recording. lnpuT The volTage average value in The daTa Table. 5.7 DisconnecT The wire beTween C3 and C4. Use mulTimeTer's \"resisTanT funcTion" To measure resisTance value (R23) beTween 82 and $6, record H in The Table. 6. CalculaTe currenT passing Through each resisTor by using equaTion i To 6 and enTer in The daTa Table. 7. CalculaTe The percenT error beTween measured currenT and The calculaTed currenT values in The sTep 6 for each resisTor. 8. Verify equaTion i To 6. Data Table DC Voltage Source (Voltage across B1 and B4) Voltage across J4 and J8 R2 R3 Resistance (Q) R1 R23 Rtotal Measured Resistance (Q) R23 Rtotal Calculated Resistance (Q) Itotal I3 123 11 12 Measured Current (A) AV3 AV23 AV tot Measured Voltage (V) AV AV2 Itotal Calculated Current (A) 12 13 I23 (Using Equation 1 to 6) Current % error Verify equation 1 to 6