Keywords: receiver sensitivity, spread spectrum, digital communication receiver, CDMA, WCDMA, bit energy, noise power spectral density, signal-to-noise ratio, SNR, signal power
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APPLICATION NOTE 1140

Abstract: The following application note provides insight into how the sensitivity of a spread spectrum application is defined and how the desired sensitivity level for digital communication receivers can be calculated. This technical paper provides a step-by-step development of the receiver sensitivity equation and concludes with numeric example, putting its mathematical definition to the test.

In a spread spectrum digital communication receiver, the relationship between the link metric E_{b}/N_{o} (bit energy to noise power spectral density ratio) and the RF power level to achieve the desired receiver sensitivity is derived from the standard noise factor definition, F. Resulting in the receiver sensitivity equation, this relationship is used by RF designers for CDMA, WCDMA cellular receivers and other spread spectrum systems. It allows the designer to determine the receiver parameter trade-offs in a spread spectrum link budget for any given input signal level.
## Deriving E_{b}/N_{o} Relationship From Noise Factor, F

By definition, F is the ratio of signal-to-noise at the input of a device (a single stage, multiple stages, or the complete receiver) to the signal-to-noise at the output of the same device (**Figure 1**). Since noise varies in an unpredictable manner from one point in time to the next, taking the ratio of the mean-square signal to the mean-square noise forms the signal-to-noise ratio (SNR).

*Figure 1.*

Following are the definitions for parameters used in Figure 1 and for the sensitivity equation:

S_{in} = available input signal power (W)

N_{in} = available input thermal noise power (W) = KTB_{RF}
where:

K = Boltzmann's constant = 1.381 × 10^{-23} W/Hz/K,

T = 290K at room temperature and

B_{RF} = RF carrier bandwidth (Hz) = chip rate for the spread-spectrum system

S_{out} = available output signal power (W)

N_{out} = available output noise power (W)

G = device gain (numeric)

F = device noise factor (numeric)

F is defined as follows_{out} in terms of the input noise, N_{in}
_{b} / T, where E_{b} is the energy in the bit interval in W-s and T is the bit time interval in seconds.

The relationship for the average modulating signal power for the user's data rate is calculated as follows_{b}/N_{o} is
_{o}) in a 1-bit interval.

Therefore,_{RF} being equal to the chip rate W in a spread spectrum system, the processing gain (PG = W/R_{bit}) can be defined as
_{bit} / B_{RF} = 1/PG, which results in the output signal-to-noise ratio
_{bit}), the value of E_{b}/N_{o} is numerically equal to SNR.
## Receiver Sensitivity Equation

To determine SNR for a given input signal level, solve for S_{in} from the noise factor equation
_{in} can also be expressed as
## Numeric Example

The following example is for a spread-spectrum WCDMA cellular base station receiver. Though the receiver sensitivity equation holds true for all levels of input signal level, this example uses the maximum specified input signal power at the minimum specified sensitivity in percent of the Bit Error Rate (%BER) for a given E_{b}/N_{o}. Following are the conditions for this numeric example:
_{max}, using the receiver sensitivity equation.
**Figure 2** provide additional guidance to finding NF_{max}:

Step 1: The maximum specified RF input signal at desired sensitivity is -121dBm for WCDMA.

Step 2: Subtract the E_{b}/N_{o} value of 5dB, which yields the maximum allowable noise level in the user bandwidth (12.2kHz) of -126dBm.

Step 3: Determine the maximum noise level in the RF carrier bandwidth by adding a processing gain of 25dB, which results in the maximum allowable noise level of -101dBm.

Step 4: Subtract the maximum allowable noise level from device input noise level resulting in NF_{max} = 7.1dB.

*Figure 2.*

Note: If a more efficient detector is used in the receiver design that only requires an E_{b}/N_{o} value of 3dB instead of 5dB, a receiver sensitivity level of -123dBm can be obtained for the same receiver NF_{max} of 7.1dB. On the other hand, a higher NF_{max} of 9.1dB can still be tolerated and meet the maximum specified input signal level of -121dBm at sensitivity for the reduced E_{b}/N_{o} value.
## Conclusion

Using the receiver sensitivity equation,
## References

Following are the definitions for parameters used in Figure 1 and for the sensitivity equation:

S

N

K = Boltzmann's constant = 1.381 × 10

T = 290K at room temperature and

B

S

N

G = device gain (numeric)

F = device noise factor (numeric)

F is defined as follows

F = (SSolving for N_{in}/ N_{in}) / (S_{out}/ N_{out}) = (S_{in}/ N_{in}) ×(N_{out}/ S_{out})

Nresults in_{out}= (F × N_{in}× S_{out}) / S_{in}where S_{out}= G × S_{in}

NThe average modulating signal power is defined as S = E_{out}= F × N_{in}× G

The relationship for the average modulating signal power for the user's data rate is calculated as follows

1 / T = user bit rate, RBased on the previous equations, the signal-to-noise ratio at the output of the device in terms of E_{bit}in Hz, which results in S_{in}= E_{b}× R_{bit}

Swhere KTF represents the noise power (N_{out}/ N_{out}= (S_{in}× G) / (N_{in}× G × F) =

S_{in}/ (N_{in}× F) =

(E_{b}× R_{bit}) / (KTB_{RF}× F) =

(E_{b}/ KTF) × (R_{bit}/ B_{RF}),

Therefore,

SWith the RF bandwidth, B_{out}/ N_{out}= E_{b}/N_{o}× R_{bit}/ B_{RF}

PG = BTherefore, R_{RF}/ R_{bit}

SNote: For a system that is not spread in bandwidth (that is W = R_{out}/ N_{out}= E_{b}/N_{o}× 1 / PG.

F = (SS_{in}/ N_{in}) / (S_{out}/ N_{out}) or F = (S_{in}/ N_{in}) × (N_{out}/ S_{out})

S_{in}= F × N_{in}× (S_{out}/ N_{out})

SIn a more useful logarithmic form, take 10 × log of each term yielding units of dB or dBm. With the noise figure NF (dB) = 10 × log (F), this leads to the following receiver sensitivity equation_{in}= F × KTB_{RF}× E_{b}/N_{o}× 1/PG

Sin (dBm) = NF (dB) + KTB_{RF}(dBm) + E_{b}/N_{o}(dB) - PG (dB)

- The maximum specified input signal level has to meet the minimum specified system sensitivity for a 12.2kbps digital voice data rate signal at -121dBm.
- The specified BER (0.1%) can be achieved for an E
_{b}/N_{o}value of 5dB for the QPSK modulated signal. - The RF bandwidth is equal to the chip rate, which is 3.84MHz.

- KTB
_{RF}(log) = 10 × log(1.381 × 10^{-23}W/Hz/K × 290K × 3.84MHz × 1000mW/W) = -108.13dBm. - For a specified user data rate of R
_{bit}equal to 12.2kbps, PG is PG = R_{chip}/ R_{bit}= 314.75_{numeric}or 25dB_{log}. - Substituting these values and solving for S
_{out}/ N_{out}= E_{b}/N_{o}× R_{bit}/ B_{RF}yields the output signal-to-noise ratio as 5dB - 25dB = -20dB. This shows that spread spectrum systems actually operate with negative SNR for a spread bandwidth.

SThe following steps and_{in}(dBm) = NF (dB) + KTB_{RF}(dBm) + E_{b}/N_{o}(dB) - PG (dB)

Step 1: The maximum specified RF input signal at desired sensitivity is -121dBm for WCDMA.

Step 2: Subtract the E

Step 3: Determine the maximum noise level in the RF carrier bandwidth by adding a processing gain of 25dB, which results in the maximum allowable noise level of -101dBm.

Step 4: Subtract the maximum allowable noise level from device input noise level resulting in NF

Note: If a more efficient detector is used in the receiver design that only requires an E

Sderived from the noise factor definition, designers can determine the receiver parameter trade-offs in a spread spectrum link budget for any given input signal level, which makes it particularly useful to determine system sensitivity._{in}(dBm) = NF (dB) + KTB_{RF}(dBm) + E_{b}/N_{o}(dB) - PG (dB)

*CDMA Systems Engineering Handbook*, Jhong Sam Lee & Leonard E. Miller, Artech House Publishers, 1998.*CDMA RF System Engineering*, Samuel C. Yang, Artech House Publishers, 1998.

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APP 1140: APPLICATION NOTE 1140,AN1140, AN 1140, APP1140, Appnote1140, Appnote 1140 |