Answer to Question #247935 in Electric Circuits for fernando lim

1.

the wavelength:

"\\lambda=vT"

where v is wave speed,

T is period

"\\lambda=17v"

2) Noise voltage is given by, "V^2=4kT \\int_{f1}^{f2} Rdf"

Where V= RMS input noise voltage, "f_2-f_1=band \\space width=3.33KHz=3.33\\times 10^3Hz"

k= Boltzmann constant"=1.38\\times 10^{-23}J\/K"

T=temperature in kelvin =29+273=302K

"R=Resistance=42\\Omega"

Now, "V=(4kTR(f_2-f_1))^{0.5}=(4\\times1.38\\times 10^{-23}\\times 302\\times42\\times 3.33\\times 1000)^{0.5}=482.86\\times 10^{-10}V"

3) Signal-to-noise ratio "=2.3\/0.7=23\/7=23:7"

4) Initial frequency f_i = 73 kHz

Final frequency f_f = (73 + 18) kHz = 91 kHz

Let Station 1, Station 2 and Station 3 be A, B and C respectively.

The f_USB of A = 73 kHz + f_m (6 kHz) = 79 kHz

The f_USB of B = 79 kHz + f_m (6 kHz) = 85 kHz

The f_USB of C = 85 kHz + f_m (6 kHz) = 91 kHz

Where: f_USB is the Frequency of the Upper Side-bands, while f_m is the modulating frequency at which each station is allowed to transmit.

Therefore, the frequency of the upper and lower side-bands of each station are given by:

1. For A, f_LSB = 73 kHz and f_USB = 79 kHz;
2. For B, f_LSB = 79 kHz and f_USB = 85 kHz;
3. For C, f_LSB = 85 kHz and f_USB = 91 kHz.

Note: f_LSB means Frequency of the Lower Side-bands.

5) Root mean square value of the shot noise current i_n is given by the Schotty formula:

I_n="\\sqrt{2\\Iota{q}\\Delta\\Beta}"

Where:

"\\Iota" =Dc current in Amperes

q= charge of an electron in Coulombs

"\\Delta""\\Beta" = the bandwidth in Hertz

Substituting

I_n= "\\sqrt{2\u00d70.5\u00d710^{-3}\u00d71.602\u00d710^{-19}\u00d710\u00d710^3}"

"\\sqrt{2\u00d70.5\u00d710^{-3}\u00d71.602\u00d710^{-19}\u00d710\u00d710^3}"

I_n =1.266"\u00d710^{-9}A"

=1.266nA