# How to use Z3 SMT-LIB online to solve problems with Operational Amplifiers

In a previous post some problems involving operational amplifiers were solved using Z3Py online. But now that Z3Py online is out of service I am trying to solve such problems using Z3 SMT-LIB online.

Example 1:

Find the value of R in the following circuit

This problem is solved using the following code:

``````(declare-const R Real)
(declare-const V1 Real)
(declare-const V2 Real)
(declare-const Vo Real)
(declare-const I1 Real)
(declare-const I2 Real)
(declare-const g Real)
(assert (= (/ V1 (+ R -50)) I1))
(assert (= (/ V2 (+ R  10)) I2))
(assert (= (* (* R (+ I1 I2)) -1) g))
(assert (= Vo g))
(assert (= Vo -2))
(assert (= V1 1))
(assert (= V2 0.5))
(assert (> R 0))
(assert (> R 50))
(check-sat)
(get-model)
``````

and the corresponding output is:

``````sat
(model (define-fun R () Real (root-obj (+ (^ x 2) (* (- 130) x) (- 2000)) 2))
(define-fun I1 () Real (root-obj (+ (* 6000 (^ x 2)) (* 30 x) (- 1)) 2))
(define-fun I2 () Real (root-obj (+ (* 2400 (^ x 2)) (* 300 x) (- 1)) 2))
(define-fun V2 () Real (/ 1.0 2.0))
(define-fun V1 () Real 1.0)
(define-fun Vo () Real (- 2.0))
(define-fun g () Real (- 2.0)) )
``````

Run this example online here

As you can see the output from Z3 is a quadratic equation on x. Then the question is: How such equation could be solved using Z3?

The output contains three algebraic numbers. For example, `R` is assigned to the 2nd root/zero of the polynomial `x^2 - 130 x - 2000`. This is a precise representation for irrational numbers that are zeros of polynomials. It may be hard to interpret. Thus, we can also ask Z3 to display the result using decimal notation.

``````(set-option :pp-decimal true)
``````

Z3 will append a `?` to denote that the output is truncated. Here is the same problem with this option. With this option, we get the following output:

``````sat
(model
(define-fun R () Real
143.8986691902?)
(define-fun I1 () Real
0.0106497781?)
(define-fun I2 () Real
0.0032488909?)
(define-fun V2 () Real
0.5)
(define-fun V1 () Real
1.0)
(define-fun Vo () Real
(- 2.0))
(define-fun g () Real
(- 2.0))
)
``````