berkeman said:I'm having a little trouble undstanding the circuit diagram. What are the "1" and "Z"? Are they meant to represent static quantities? Or is Z a varying input? Or is Z really a 2, like in 2.0V?
As for solving for V+ and V- and Vout, just write the sum of all currents into the + node is zero and do the same for the - node. Since the opamp is ideal, what simplification does that let you make?
Yeah, heck if they're static voltages, then you can solve for Vo directly. Just write the two equations for the V- and V+ inputs and solve for Vo. You didn't answer my quiz question yet about what properties does an ideal opamp have that makes this problem easier...mugzieee said:the "1",".25",".75",".67", and "2" are all voltages. are you saying that i should right nodal equations for the inputs? i didnt quite understand what you meant...
berkeman said:Yeah, heck if they're static voltages, then you can solve for Vo directly. Just write the two equations for the V- and V+ inputs and solve for Vo. You didn't answer my quiz question yet about what properties does an ideal opamp have that makes this problem easier...
berkeman said:I was referring to the first two that you listed. Very high gain, and zero input current. That let's you assume that Vin+ = Vin-, and just write the voltage divider equation for the + input. Set the - input voltage to the same, and write the voltage divider equation for the - input, including the Vo term. Then just solve for Vo.
No, or at least I'm not tracking what you are writing.mugzieee said:ok so from what i understand from what you said, here is what i have done:
.067/2000 + 2/4000 + -2/4000 + ((2-v_o)/50000) = 1/2000 + 0.25/3000 + 0.75/5000
then i solve for v_o?
does that look correct?
berkeman said:No, or at least I'm not tracking what you are writing.
Start with figuring out the voltage at the Vi+ terminal of the opamp. You should write the sum of the three curents into the Vi+ terminal (in terms like (1.0V - Vi+)/2000, and set that sum equal to zero. Then solve for Vi+. Then set Vi- = Vi+, and write the sum of the four currents into the Vi- node and set that sum to zero. That sum will have one term that looks like (Vo - Vi-)/50000, plus three other terms. The only unknown is Vo, so just solve for it then.
EDIT -- Fixed a typo.
Vi+ is not ground, so to find the current through the resistor, you need to take the voltage *difference* across the resistor and divide it by the resistance.mugzieee said:what confuses me is that why can't the current i_1= 1/2k, i_2=.25/3k, i_3=.75/5k for the currents entering v_i+?
also would the current into the node with the two 4k resistors be 2/4k + 0-v_i-/4k?
mugzieee said:heres another shot:
((1-v_i+)/2000) + ((.25-v_i+)/(3000)) + ((.75-v_i+)/5000)) = 0
v_i+=.7097
v_o-=v_i+
((v_o- - .7097)/(50000)) + ((1-.7097)/(2000)) + ((2-.7097)/(4000)) + ((0-.7097)/(4000))=0
v_o-=-13.81
An OP AMP is an electronic device that amplifies the difference between two input voltages. It has a high gain and is often used in signal processing and analog circuits.
A difference OP AMP amplifies the difference between two input voltages, while a summing OP AMP combines two or more input voltages to create an output voltage that is the sum of all the inputs.
A difference OP AMP has two inputs, an inverting input (-) and a non-inverting input (+). The output voltage is equal to the difference between the two input voltages multiplied by the gain of the OP AMP. The inverting input is used to amplify the difference between the two input voltages, while the non-inverting input is used to set the reference voltage.
A summing OP AMP has two or more inputs, each with its own resistor connected to the inverting input. The output voltage is equal to the sum of all the input voltages multiplied by their respective resistor values. The inverting input acts as a virtual ground, ensuring that the current through each resistor is equal to the current flowing through the feedback resistor, resulting in the summing function.
Difference OP AMPs are commonly used in instrumentation amplifiers, audio amplifiers, and signal processing circuits. Summing OP AMPs are often used in audio mixers, voltage regulators, and analog-to-digital converters.