Sp-3-4350. 120-rv3 (to become ansi/tia-470. 120-C) Draft 22a ast ballot Comments with track changes on Telecommunications Telephone Terminal Equipment Transmission Requirements for Analog Speakerphones


Technical Requirements 4.1Categories of Criteria



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4Technical Requirements

4.1Categories of Criteria


Four types of requirements are specified in this standard: Mandatory, Recommended, Permissive and Advisory:

Mandatory requirements are designated by the terms “shall” and “shall not.” These requirements are used to indicate conformity in which no deviation is permitted.

Recommended requirements are designated by the terms “should” and “should not.” These requirements generally relate to compatibility or performance advantages towards which future designs should strive.

4.2General Testing Considerations


These requirements apply to measurements made in a laboratory consisting of an anechoic chamber, and possibly a test table and/or a test wall and that can be repeated from lab to lab. These requirements do not apply to measurements made in a real room with environmental reflections. These measurements shall be performed with a free-field microphone and artificial mouth in accordance with IEEE Std1329. If the device under test includes multiple housings (excluding cordless phones) or inherently involves environmental reflections other than a test table or test wall (e.g. office cubicle) then a HATS shall be used in accordance with IEEE Std 1329.

4.3Test Circuits and Setups


The following test circuits and setups are referenced in this document:

4.3.1General Send Test Setup


Figure 1 – General Test Setup For Send Measurements


4.3.2General receive Test Setup


Figure 2 – General Test Setup For Receive Measurements


4.3.3Send Testing Circuit with Artificial Lines


Figure 3 – Test Circuit For Send Measurements


4.3.4Receive Testing Circuit with Artificial Lines


Figure 4 – Test Circuit For Receive Measurements




4.3.5DC Feed Circuit


The dc feed circuit must supply the CPE power and interface to test equipment such that the required parameters may be measured without introducing any significant error. The dc feed shall provide the following:

  • 50 Vdc in series with 400 ohms +/- 1%

  • less than 0.1 dB insertion loss over the 100 Hz to 10 kHz range

NOTE: See IEEE Std 269 for the procedure to follow when determining feed circuit loss.

  • At least 30 dB return loss with respect to 900 ohms over the 300 Hz to 10 kHz range

One possible implementation of the dc Feed is shown in Figure 5.



NOTES:

  1. C >= 100 uF

  2. L >= 5 H

  3. R = 200 ohms (including resistance of L)

  4. V = 50 Vdc

  5. This is a simplified DC feed circuit. It does not implement the current limit characteristic of modern end offices, which typically limit the maximum current supplied by the office.

Figure 5 – One Possible dc Feed Circuit

4.3.6Termination Impedance


The termination impedance shall be a resistive load of 900 ohms with a tolerance of +/- 1 %.

4.3.7Source Impedance


The source impedance shall be a 900 ohms with a tolerance of +/- 1 %.

4.3.8Artificial Lines


This standard has transmission requirements for CPE when connected to 0 km, 2.7 km and 4.6 km artificial lines. These lines may be assembled using combinations of artificial line segments shown in Figure 6 with component values selected from Table 1. These artificial line segments represent 26 AWG non-loaded cable.

Figure 6 – Artificial Line Segment

Table 1 – Artificial Line Segment Component Values


Component

0.305 km (1 kft)

0.914 km (3 kft)

1.83 km (6 kft)

R1, R4

41.7 

124 

249 

R2, R3

109 

174 

312 

C1, C4

3.77 nF

11.3 nF

22.6 nF

C2, C3

4.02 nF

12.2 nF

25.5 nF

L1, L2

96.0 H

336 H

983 H

NOTES:

(1) All values are 1 %.

(2) 2.7 km (9 kft) and 4.6 km (15 kft) can be made up of cascaded sections of the above.



4.4Transmission Performance


The transmission performance of a speakerphone is determined by its acoustical-to-electrical and electrical-to-acoustical transfer characteristics. A free field microphone (see ANSI S1.12) and P.51 compliant mouth simulator or a Head and Torso Simulator (HATS) with a Type 3.3 or a Type 3.4 ear simulator (see ITU-T Recommendation P.57) shall be used for all transmission performance measurements. If a HATS is used it shall be equipped with both a right and left ear simulator. Mouth and ear simulator calibration shall be performed according to IEEE Std 1329. The measuring equipment and the speakerphone shall be positioned as described in IEEE Std 1329 . The Test Table used shall meet the requirements of IEEE Std 1329.

The default test signal for speakerphones shall be the ITU-T Recommendation P.50 male. The long term spectral average of P.50 Artificial Speech is very similar to real speech. Any test signal that produces identical results is considered an acceptable test signal. In the rare case that it can be shown that P.50 is not an appropriate test signal for a specific device, a real speech test signal may be used.


4.4.1Send Performance


The send performance of a speakerphone is determined by its acoustical-to-electrical transfer characteristics. To determine the send performance, requirements for frequency response, Send Loudness Rating (SLR), directionality (SLRD), distortion, noise and, if supported, muting are specified. The minimum receive volume control setting is used for all send measurements.

NOTE: Informative Send Level and Send Level Directionality test methods are provided in Annex I.5.

4.4.1.1Send Frequency Response

4.4.1.1.1Requirement

The send frequency response for a 2.7 km artificial line shall fall within the upper and lower limits in Table 2 (shown in Figure 7). These are floating limits, which are positioned vertically for the best fit to the actual measurement.
4.4.1.1.2Method of Measurement

  1. The send frequency response shall beis measured using 0 km, 2.7 km, and 4.6 km artificial lines using the test setup and circuit shown in Figure 1 and Figure 3.

  2. The nominal P.50 stimulus test signal level shall beis +0 dBPa at the MRP and .

  3. the test signal for this test shall be the ITU-T Recommendation P.50 male artificial speech signal. Tthe measurement shall isbe made over a minimum range of 100 Hz through 8000 Hz using real-time analysis with 1/3 octave or smaller bands averaged over the entire duration of the test signal. If smaller bands are used then the response shall be band averaged to 1/3 octave before applying the mask.

  4. The send frequency response is the ratio of the speakerphone electrical output spectrum to the acoustic test stimulus spectrum expressed in terms of dBV/Pa.

  5. Apply the floating mask limits of Table 2 (shown in Figure 7) to the measured 2.7km frequency response.

Table 2 – Send Frequency Response Limits

Nominal
1/3 Octave Band
(Hz)


Lower Band Mask Limit

(Hz)


Upper Band Mask Limit

(Hz)


Send Response Limit

(dB)

Upper Limit

100

89.1

112

-3.5

125

112

141

0.5

160 to 1000

141

1122

3.5

1250

1122

1413

5.5

1600

1413

1778

7.5

2000 to 3150

1778

3548

8.5

4000

3548

4467

3.5

Lower Limit

315

282

356

-9.5

400

356

447

-8.5

500

447

562

-7.5

630

562

708

-6.5

800

708

891

-5.5

1000 to 2000

891

2239

-3.5

2500

2239

2818

-6.5

3150

2818

3548

-9.5

Figure 7 – Send Frequency Response Limits for 2.7 km


4.4.1.2Send Loudness Rating (SLR)


Correlation factors relating speakerphone loudness ratings to handset loudness ratings are used in this standard. The currently accepted correlation factors for personal, wireline telephone applications are noted below. These correlation factors may not be appropriate for other speakerphone applications such as conference, hand-held, or any applications where the relationship between the talker and the speakerphone varies from the 50 cm position, or the reverberation characteristics or the background noise levels vary from typical home/office environments. The speakerphone SLR should be 5 dB quieter than the handset SLR due to:

  • A 3 dB increase in the average talking level when using a speakerphone

  • A 1-2 dB decrease in the actual handset talking levels compared to those measured at the MRP

  • Other small differences related to different frequency responses, etc.



4.4.1.2.1Requirement

The SLR values for 0 km, 2.7 km, and 4.6 km artificial lines shall be calculated from the send frequency response measurements (4.4.1.1) as described in Annex C and shall fall within the ranges given in Table 3.

Table 3 – Send Loudness Rating (SLR) Limits



Send Loudness Rating (SLR)

Artificial line, km

Nominal

dB

Mandatory

Range, dB

0

11

16 to 4

2.7

13

18 to 8

4.6

15

22 to 10

NOTES:

  1. Loudness rating values represent system losses. More positive values of SLR represent quieter send levels.

  2. Send Automatic Gain Control (AGC) is a subject for further study which may be addressed in the next revision of this standard.

  3. The range is +/- 5 dB for the nominal loop. The upper limit is 2 dB louder at 0 km and the lower limit is 2 dB quieter at 4.6 km to allow for the lack of loop compensation.


4.4.1.3Send Loudness Rating Directionality (SLRD)

4.4.1.3.1Requirement

The SLRD values should be within the limits given in Table 4.

Table 4 – Send Loudness Rating Directionality Limits.



Angle

Degrees CCW

SLRD

(dB)

30

+/- 3

60

< -3

300

< -3

330

+/- 3

NOTES:

  1. The intent is to have consistent loudness when the talker is +/- 30 degrees from the center axis.

  2. The intent is to ensure that there is no more than 3dB gain when the talker is +/- 60 degrees from the center axis.


4.4.1.3.2Method of Measurement

  1. The Send Loudness Rating is first measured according to 4.4.1.2 at the 0 degree angle.

  2. The speakerphone is then rotated about its physical center 30 degrees counter-clockwise. Take care to keep the MRP of the artificial mouth at a constant distance from the physical center of the speakerphone, see Figure 8. Repeat the SLR measurement.

  3. Successively rotate the speakerphone about its physical center to the 60, 300, and 330 degree positions and repeat the SLR measurement at each position.

  4. Calculate the SLRD for each angle as the difference between the SLR at that angle and the SLR at 0 degrees





NOTES:

  1. The Speakerphone setup at the 0 Degree position is using the Reference Triangle.

  2. For the other test positions the Speakerphone is rotated around its the physical center.

  3. Test table is at least 1 meter square.

Figure 8 – Speakerphone Send LR Directionality Measurement Setup

4.4.1.4Send Distortion and Noise

4.4.1.4.1Requirement

  1. The ratio of the signal power to the total distortion and noise power of the signal output shall be above the limits given in Table 5 and Table 6.

  2. Use IEEE Std 269 to determine if the product is activated for each test point, especially at lower test levels. Activation threshold is dependent on both level and frequency. For any point that is not activated this requirement does not apply. It is recommended that the send distortion and noise performance also be confirmed using subjective listening tests.

Table 5 – Limits for Send SDNR vs Frequency

Center Frequency (Hz)

SDNR (dB)

(+5dBPa Send Level)

500

26

800

26

1000

26

Table 6 – Limits for Send SDNR vs Level

Send Level at the MRP

(dBPa)

SDNR (dB)

(800 Hz)

-10

26

-5

26

0

26

NOTE: 26 dB = 5%
4.4.1.4.2Method of Measurement

  1. Send distortion and noise is measured according to IEEE Std 1329 using the test setup and circuits shown in Figure 1 and Figure 3 with 0 km and 4.6 km artificial lines.

  2. The test stimulus is white noise band limited to 1/3rd octave and pulsed 250ms ON, 150ms OFF.

  3. Apply the test signal at the MRP, at the levels given in Table 6 using the center frequencies and band limits specified below:

Table 7 – Send SDNR Stimulus Center Frequencies and Band Limits

Center Frequency

Band Edges

(Hz)

    500

    410

    595

    800

    675

    925

    1000

    855

    1155

  1. Process the measured data using Hanning Windowing with 5Hz resolution FFT from 100Hz to 6000Hz. After time averaging, remove the data within the notch frequency band specified below:

Table 8 – Send SDNR Analysis Notch Frequency Band

Center Frequency

Notch Band Edges

(Hz)

    500

    405

    600

    800

    670

    930

    1000

    850

    1160

  1. Calculate the ratio of the signal power to the total Psophometric-weighted distortion and noise power of the signal output.


4.4.1.5Send Off-Hook Noise

4.4.1.5.1Requirement

The psophometric-weighted telephone set noise (see Annex A) shall not exceed -69 dBmp when measured with 0 km, 2.7 km and 4.6 km artificial lines over a minimum period of 5 seconds.
4.4.1.5.2Method of Measurement

The send off-hook noise measurement shall beis made as described in IEEE Std 1329 from 100Hz to 6000Hz. The speakerphone noise shall beis measured using the test circuits shown in Figure 1 and Figure 3 except no signal shall be applied at the MRP. The noise shall isbe measured under the following conditions:

  1. The measurements shall beare made in the Off-Hook mode with 0 km, 2.7 km, and 4.6 km artificial lines.

  2. The speakerphone microphone shall beis isolated from sound input and mechanical disturbances with the. The background noise level shall be less than 29 dBA.

  3. The measurement shall be taken over a minimum period of 5 seconds.

  4. Microphone Muting shall is not to be used to provide room noise isolation.

  5. Per IEEE Std 1329, sSteps should need to be taken to ensure the speakerphone is fully operating in the send mode.


4.4.1.6Send On-Hook Noise

4.4.1.6.1Requirement

The telephone set noise shall not exceed -80 dBmp with a 0 km artificial line measured over a minimum period of 5 seconds.
4.4.1.6.2Method of Measurement

The telephone set noise shall beis measured using the test setup and circuit shown in Figure 1 and Figure 3 except no signal shall beis applied at the MRP.


4.4.1.7Send Off-Hook Send Single Frequency Interference

4.4.1.7.1General

Narrow-Band noise, including single frequency interference, is an impairment that can be perceived as a tone depending on its level relative to the overall weighted noise level. This test measures the weighted noise level characteristics in narrow bands of not more than 31 Hz.
4.4.1.7.2Requirement

The send single frequency interference shall not exceed -78 dBmp with 0 km, 2.7 km and 4.6 km artificial lines when measured over a minimum period of 5 seconds.
4.4.1.7.3Method of Measurement

The speakerphone noise shall is be measured using the test setup and circuit shown in Figure 1 and Figure 3 except no signal shall be applied at the MRP. The noise shall be measured under the following conditions:

  1. The measurements shall beare made in the Off-Hook mode with 0 km, 2.7 km, and 4.6 km artificial lines.

  2. The speakerphone microphone shall beis isolated from sound input and mechanical disturbances with . Tthe background noise level shall be less than 29 dBA (as specified in IEEE Std 1329).

  3. Measure the psophometric-weighted noise level with a selective voltmeter or spectrum analyzer with an effective bandwidth of not more than 31 Hz, over the frequency range of 100 to 3500 Hz.

  4. If FFT analysis is used, then “Flat Top” windowing shall be employed.

  5. Microphone Muting shall is not be used to provide room noise isolation.



4.4.1.8Send Muting

4.4.1.8.1Requirement

If supported, the send muting (i.e., manual mute mode selection) shall be determined over the frequency range of 100 Hz to 8000 Hz. During muting, any transmitted signal in the frequency range for 0 km, 2.7 km, and 4.6 km artificial lines shall not exceed -80 dBV at the SETP.
4.4.1.8.2Method of Measurement

The send muting shall be is measured using the test setup and circuit shown in Figure 1 and Figure 3.

  1. The P.50 stimulus level is 0 dBPa at the MRPSet the Mouth simulator level to 0 dBPa.

  2. The Send Muting measurement shall beare made with 0 km, 2.7 km and 4.6 km artificial lines.

  3. This measurement should is be done performed with a narrow band meter that has a noise floor less than –86 dBV.


4.4.2Receive Performance


The receive performance of a speakerphone is determined by its electrical-to-acoustical transfer characteristics. To determine the receive performance, requirements for frequency response, Receive Loudness Rating (RLR), Receive Loudness Rating Directionality (RLRD), linearity, signal-to-distortion and noise (SDNR), noise and volume control are specified.

The speakerphone receive volume control shall be set to the applicable Reference Volume Control Setting for the test loop when checking for receive characteristic compliance, unless specifically stated otherwise. The stimulus levels specified for receive tests are specified as 900 ohm nominally loaded (one-half of the open circuit voltage). Following a calibration, the resistive load is removed and the source is connected to the speakerphone without further adjustment.


4.4.2.1Receive Level


The CPE is expected to receive a wide dynamic range of input speech levels. A speaker volume control (manual or automatic or both) provides a means to compensate for this variable input level. The lowest volume control setting that meets the level requirements for each test loop is considered the reference volume control setting for that loop and is to be utilized for all applicable receive testing. Different volume control settings may be used to meet the requirements at the different test loops. (See Reference VC definitions in 3.2.)
4.4.2.1.1Requirement

  1. To ensure adequate volume control gain, the CPE shall meet the acoustic level requirements in Table 9.

  2. To ensure adequate volume control attenuation, the CPE shall have at least one volume control setting that will produce a receive level of less than 60dBSPL with a test level of -18dBV (0km loop).

Table 9 – Speakerphone Receive Level Limits

Condition

Input Level

Loop

Acoustic Level Limit

High Level, short loop

-18 dBV

0 km

 65 dB SPL

Nominal Level, mid loop

-25 dBV

2.7 km

 65 dB SPL

Low Level, long loop

-32 dBV

4.6 km

 62 dB SPL

NOTES:

The test signal input levels were derived as follows:



  1. High Level (-18dBV): Highest level possible for using P.50 without the PSTN clipping the test signal.

  2. Nominal Level (-25dBV): Represents the mean Far-End Active Speech Level (ASL) (-28dBm) at the CPE recorded in Bellcore SR-2476 Annex B.

  3. Low Level (-32dBV): Represents two standard deviations (2 x 4.5dB = 9dB) from the mean Far-End Active Speech Level (ASL) (-37 dBm) at the CPE recorded in Bellcore SR-2476 Annex B. Switched loss (for echo suppression) may squelch lower levels.

  4. The requirements above would allow acceptable receive levels with average room noise levels. For higher room noise levels and user hearing variability (e.g. hearing loss), a higher output level (i.e. 70 dBSPL) would allow for a better user listening experience.


4.4.2.1.2Method of Measurement

  1. Configure the CPE and test equipment as shown in Figure 2 and Figure 4.

  2. The test signal for this test is the ITU-T P.50 male artificial speech signal.

  3. Set the signal generator for a nominally loaded level per the levels in Table 9:

  4. The measurement is be made over a minimum range of 100 Hz through 8000 Hz using real-time analysis with 1/3 octave or smaller bands averaged over the entire duration of the test signal.

  5. The 100 Hz through 8000 Hz measurement result is then power summed and expressed in terms of dBSPL.


4.4.2.2Receive Level Directionality (RLD)

4.4.2.2.1Requirement

The RLD values should be within the limits given in Table 10.

Table 10 – Receive Level Directionality Limits.



Angle Degrees

Position (CCW)

RLD

(dB)

30

+/-5

60

+/-5

300

+/-5

330

+/-5


4.4.2.2.2Method of Measurement

  1. The Receive Level shall is first be measured according to 4.4.2.1 at the 0 degree angle at -25dBV with a 2.7 km artificial line.

  2. The speakerphone is then rotated about its physical center 30 degrees counter-clockwise. Take care to keep the grid of the measurement microphone at a constant distance from the physical center of the speakerphone, see Figure 9. Repeat the Receive Level measurement.

  3. Successively rotate the speakerphone about its physical center to the 60, 300, and 330 degree positions and repeat the Receive Level measurement.

  4. Calculate the RLD for each angle as the difference between the Receive Level at that angle and the Receive Level at 0 degrees.





NOTES:

  1. The Speakerphone setup at the 0 Degree position is using the Reference Triangle.

  2. For the other test positions the Speakerphone is rotated around its the physical center.

  3. Test table is at least 1 meter square.

Figure 9 – Speakerphone Receive Level Directionality Measurement Setup

4.4.2.3Receive Frequency Response

4.4.2.3.1Requirement

The receive frequency response recorded for a 2.7 km artificial line shall fall within the upper and lower limits in Table 11 (shown in Figure 10) between 100 Hz and 8 kHz. These are floating limits, which are positioned vertically for the best fit to the actual measurement.

Table 11 – Mandatory Receive Frequency Response Limits



1/3
Octave Band


(Hz)

Lower Band Mask Edge

Upper Band Mask Edge

Receive Response Limit (dB)

Upper Limit

100

89.1

112

-4

125

112

141

-1

160

141

178

2

200 to 4000

178

4467

5

5000

4467

5623

-2

6300

5623

7079

-9

8000

7079

8913

-15

Lower Limit

400

355

447

-6

500 to 2000

447

2239

-5

2500

2239

2818

-8

3150

2818

3548

-11

Table 11 does not include a mandatory lower limit for frequencies below 400 Hz. It is desirable for the receive response to exceed a lower limit mask value of -7dB for the 315 Hz 1/3 octave band (282 Hz to 356 Hz band edges).



4.4.2.3.2Method of Measurement

  1. Configure the CPE and test equipment as shown in Figure 2 and Figure 4.

  2. The test signal for this test is the ITU-T P.50 male artificial speech signal.

  3. The receive frequency response shall be measured with the CPE at the Reference Volume Control setting for the 2.7km artificial line using the nominal level (-25dBV) and the test circuit shown in Figure 2 and Figure 4.

  4. The P50 test signal is applied and the The measurement shall be made over a minimum range of 100 Hz through 8000 Hz using real-time analysis with 1/3 octave or smaller bands averaged over the entire duration of the test signal. If smaller bands are used then the response shall be band averaged to 1/3 octave before applying the mask.

  5. The receive frequency response is the ratio of the speakerphone acoustic output spectrum to the electrical input test stimulus spectrum expressed in terms of dBPa/V.

  6. Apply the floating mask limits of Table 11 (shown in Figure 10) to the measured 2.7km frequency response.

Figure 10 – Receive Frequency Response Limits for 2.7 km




4.4.2.4Receive Distortion and Noise

4.4.2.4.1Requirement

  1. The ratio of the signal power to the total A-weighted distortion and noise power should be greater than or equal to the limits given in Table 12 and Table 13. (AST - Are these really a SHOULD requirement or are these SHALL requirements as with the Send SDNR? If “should” perhaps these requirements can become “shall” after a 2 year period following publication)

  2. A Receive Level (e.g. -30 dBV) is only to be tested if the measured sound pressure is greater than -50 dBPa (44 dBSPL).

Table 12 – Limits for Receive SDNR vs Frequency

Center Frequency (Hz)

Receive Ratio (dB)

(-15dBV Test Level)

500

26

800

26

1000

26

Table 13 – Limits for Receive SDNR vs Level

Receive Level

(dBV)

Receive Ratio (dB)

(800 Hz)

-30

26

-25

26

-20

26

NOTE: 26 dB = 5%


4.4.2.4.2Method of Measurement

  1. Receive distortion and noise is measured according to IEEE Std 1329 using the test setup and circuits shown in Figure 2 and Figure 4 with 0 km and 4.6 km artificial lines using the applicable Reference VC setting for each loop.

  2. The test stimulus is white noise band limited to 1/3rd octave and pulsed 250ms ON, 150ms OFF.

  3. Apply the test signal at the levels given in Table 13 using the center frequencies and Band Limits specified below:

Table 14 – Receive SDNR Stimulus Center Frequencies and Band Limits

Center Frequency

Band Edges (Hz)

    500

    410

    595

    800

    675

    925

    1000

    855

    1155



  1. Process the measured data using Hanning Windowing with 5Hz resolution FFT from 100Hz to 8000Hz. After time averaging, remove the data within the notch frequency band specified below:

Table 15 – Receive SDNR Analysis Notch Frequency Band

Center Frequency

Notch Band Edges (Hz)

    500

    405

    600

    800

    670

    930

    1000

    850

    1160



  1. Calculate the ratio of the signal power to the total A-weighted distortion and noise power of the signal output.


4.4.2.5Receive Off-Hook Noise

4.4.2.5.1Requirement

The acoustic noise level from the speakerphone at the applicable Reference Volume Control Setting shall not exceed 40 dBA for 0 km, 2.7 km, and 4.6 km artificial lines when measured over a minimum period of 5 seconds.
4.4.2.5.2Method of Measurement

The measurement shall isbe made as described in IEEE Std 1329 at a distance of 25cm. The speakerphone noise shall be measured using the test setup and circuit shown in Figure 2 and Figure 4 except no signal shall isbe applied at the RETP. The noise shall isbe measured under the following conditions:

  1. The measurements shall beare made in the Off-Hook mode with 0 km, 2.7 km, and 4.6 km artificial lines using the applicable Reference VC setting for each loop.

  2. The measurement microphone shall isbe isolated from sound input and mechanical disturbances with the . The background noise level shall be less than 29 dBA (as specified in IEEE Std 1329).

  3. The measurement shall be taken over a minimum period of 5 seconds.

  4. Microphone Muting shall is not to be used to provide room noise isolation.


4.4.2.6Receive Off-Hook Single Frequency Interference

4.4.2.6.1General

Narrow-Band noise, including single frequency interference, is an impairment that can be perceived as a tone depending on its level relative to the overall weighted noise level. This test measures the weighted noise level characteristics in narrow bands of not more than 31 Hz, which can then be compared to the overall weighted background noise level.
4.4.2.6.2Requirement

The receive A-weighted single frequency interference at the Reference Volume Control Setting shall be 10 dB quieter than the A-weighted broadband noise floor when measured over a minimum period of 5 seconds.
4.4.2.6.3Method of Measurement

  1. Receive noise is measured according to IEEE Std 1329, using the test setup and circuit shown in Figure 2 and Figure 4 except no signal shall be applied at the RETP.

  2. The A-weighted noise level is measured with a selective voltmeter or spectrum analyzer having an effective bandwidth of not more than 31 Hz, over the frequency range of 100 to 8000 Hz.

  3. If FFT analysis is used, then “Flat Top” windowing shall beis employed.

  4. The ambient noise for this measurement shall not exceed 29 dBA.




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