rev. 0.3 3/13 copyright ? 2013 by silicon laboratories AN603 AN603 si4822/26/27/40/44-demo b oard t est p rocedure 1. introduction the purpose of this document is to describe the test pr ocedures used in silicon laboratories for the si4822/26/27/ 40/44-demo am/fm/sw tuner board. it is also intended to enable cust omers to exactly replicate silicon laboratories? test envir onment so that variances in cu stomers? and silicon laboratories? measured results can be accurately compared. this document covers fm, am, and sw tests for the si4822/40 and si4826/27/44 receiver. the si4822/26/27/40/44-demo board provid es a platform to test and operate the si4822/26/27/40/44 tuner. refer to the si4822/26/27/40/44-demo board user?s guid e for the operation details of the demo board. 2. fm tuner testing setup 2.1. fm common setup fm tuner standard configuration: ?? tune exactly to 98.0 mhz. see the si4822/26/2 7/40/44-demo board user?s guide for details. ?? set volume to maximum unless otherwise specified. ?? ensure cable length between the generator and antenna input is as short as possible. figure 1. fm tuner setup with one generator �������� �
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AN603 2 rev. 0.3 figure 2. fm tuner setup with two generators fm tuner test equipment list: ?? rohde & schwarz upl audio analyzer ?? rohde &schwarz sml01 signal generator ?? mini-circuits power combiner 2.2. fm tuner t esting considerations several issues must be considered to make accura te measurements. first, the power combiner and cable lo sses must be calibrated and factored into each measurement. the loss for the mini-circuit power comb iner is approximately 6 db. second, most signal generators display the voltage genera ted at the input of the device under test (dut) assuming an input resistance of 50 . for example, if the signal generator displays vl = 1 v (0 db v), the generator source voltage vs is 2 v (6 db v). the load voltage vl is generated from the source voltage vs by the voltage divider created by the 50 generator source resistance rs and the 50 load resistance rl . this distinction is important only for sensitivity and ip3, which are specified in v emf*, where emf refers to the source voltage vs. measurements such as am suppression, selectivity, a nd spurious response are relative and may be referenced using vs or vl. to summarize, the generator displays the voltage at the input of the dut. input impedance for the si4822/26/27/40/44 fm tuner is high, so to convert the valu e displayed on the signal generator to emf, double the voltage (add 6 db). *note: emf = electro motive force ���������� ���� !�
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AN603 rev. 0.3 3 3. fm testing procedure 3.1. fm tuning frequency range 3.1.1. description the test checks the lowest possible tuning frequency an d the highest possible tuning frequency of the si4822/26/ 27/40/44 fm receiver. 3.1.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set rf level = 0 db v. b. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable modulation. d. enable carrier. 5. slide band switch or press push button to select fm1 band for testing. 6. turn tuning wheel to th e lowest possible position. 7. adjust signal generator rf (by 10 khz step), un til the measured sinad reaches maximum level. record this rf frequency as the lowest tuning frequency fmin. 8. repeat for highest tuning frequency point fmax. 9. repeat for other fm band testing.
AN603 4 rev. 0.3 3.1.3. pass criteria for the band property with mcu setting, the tuning frequency range is the range which t he user set (for setting the value of band top and band bottom in the setting menu, see the si4822/26/27/40/44-demo board user?s guide for details). for the band property with tuner default, the pass criteria are as follows: 3.2. fm sensitivity 3.2.1. description determine input level in db vemf to result in 26 db sinad in mono rx mode. 3.2.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable modulation. d. enable carrier. 5. adjust generator rf level, vrf0, until audio analyzer sinad = 26 db 1 db. 6. sensitivity (db vemf) = vrf0. 3.2.3. pass criteria fm sensitivity should be below 10 dbvemf. table 1. fm frequency range parameter min max unit fm1 frequency range 87 108 mhz fm2 frequency range 86.5 109 mhz fm3 frequency range 87.3 108.25 mhz fm4 frequency range 76 90 mhz fm5 frequency range 64 87 mhz
AN603 rev. 0.3 5 3.3. fm image rejection 3.3.1. description the test measures the fm image rejection of the tuner. 3.3.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable modulation. d. enable carrier. 5. adjust generator rf level, vrf1, until audio analyzer sinad = 26 db 1 db. 6. record the rf level = vrf1. 7. change generator carrier frequency to 97.744 mhz 8. adjust generator rf level*, vrf2, until audio analyzer sinad = 26 db 1 db. 9. image rejection (db) = vrf2 ? vrf1. note: maximum rf level setting for the r&s sml01 signal generator is 120 db v. you cannot increase the rf level beyond this value. if you adjust generat or rf level from vrf1 to 120 db v, the audio analyzer sinad still can not get to the sinad = 26 db 1 db, your image rejection will be better than 120 db v ? vrf1. 3.3.3. pass criteria fm image rejection should be more than 40 db.
AN603 6 rev. 0.3 3.4. selectivity ?3 db 3.4.1. description the test measures the fm frequency offset range to the tuned station when output audio level drops by 3 db. 3.4.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 40 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record the audio output level (dbv) = vaudio0 6. raise the signal generator rf frequency fh, until audio output level vaudio1 = vaudio0-3. 7. lower the signal generator rf frequency fl, until audio output level vaudio1 = vaudio0-3. 8. selectivity ?3 db (khz) = fh - fl. 3.4.3. pass criteria fm selectivity for ?3 db audio level difference should be between 40 khz and 100 khz.
AN603 rev. 0.3 7 3.5. fm limiting ?3 db 3.5.1. description the test measures the rf input level when audio output level drops by 3 db from the standard level. 3.5.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 94 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record the audio output level (dbv) = vaudio0 6. adjust the signal generator rf level vrf0, until audio output level vaudio1 = vaudio0-3. 7. fm limiting ?3 db (db v) = vrf0. 3.5.3. pass criteria fm limiting sensitivity for ?3 db audio level drop should be no more than 3 db v.
AN603 8 rev. 0.3 3.6. fm audio frequency response 3.6.1. description audio frequency response is the measure of linearity of ou tput voltage vs. modulation frequency across the audio band. 3.6.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select stereo modulation. i. set fm deviation = 10.5 khz. ii. set l = r. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. v. set pre-emphasis = 75 s. vi. set pilot = on. vii. set pilot deviation = 6.75 khz. d. enable modulation. e. enable carrier. 5. audio 1 khz level (dbv) = v1 khz. 6. configure audio analyzer frequency mode through rms select function.* set frequency mode = fix: 30 hz. 7. configure generator lfgen frequency = 30 hz. 8. audio 30 hz level (dbv) = v30 hz. 9. configure audio analyzer frequency mode thr ough rms select function. set frequency mode = fix: 15 khz. 10. configure generator lfgen frequency = 15 khz. 11. audio 15 khz level (dbv) = v15 khz. 12. audio frequency response (db) equals the great er magnitude of (v30 hz ? v1 khz) and (v15 khz ? v1 khz). note: if you test the ban d with de-emphasis 50 s, you should set pre-emphasis = 50 s. 3.6.3. pass criteria the greater magnitude of (v30 hz ? v1 khz) and (v 15 khz ? v1 khz) should be no more than 3 db.
AN603 rev. 0.3 9 3.7. fm stereo separation 3.7.1. description the test quantifies leakage or crosstalk from one channel to another in stereo mode. 3.7.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select stereo modulation. i. set fm deviation = 67.5 khz. ii. set l = 1, r = 0. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. v. set pre-emphasis = 75 s. vi. set pilot = on. vii. set pilot deviation = 6.75 khz. d. enable modulation. e. enable carrier. 5. left channel audio level (dbv) = vaudio l1 . 6. right channel audio level (dbv) = vaudio r1 . 7. record the audio stereo separation1 (db) = abs (vaudio l1 ? vaudio r1 ). 8. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select stereo modulation. i. set fm deviation = 67.5 khz. ii. set l = 0, r = 1. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. v. set pre-emphasis = 75 s. vi. set pilot = on. vii. set pilot deviation = 6.75 khz. d. enable modulation. e. enable carrier. 9. left channel audio level (dbv) = vaudio l2 . 10. right channel audio level (dbv) = vaudio r2 .
AN603 10 rev. 0.3 11. record the audio stereo separation2 (db) = abs (vaudio l2 ? vaudio r2 ). 12. audio stereo separation (db) = minimum (audio stereo separation1, audio stereo separation2) 3.7.3. pass criteria fm stereo separation should be greater than 32 db. 3.8. fm audio l/r imbalance 3.8.1. description the test measures the gain / level imbalance between l and r channels in stereo mode. 3.8.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 75 khz. ii. set rf level = 60 db v. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. left channel audio level (dbv) = vaudio l . 6. right channel audio level (dbv) = vaudio r . 7. audio l/r imbalance (db) = abs (vaudio l ? vaudio r ). 3.8.3. pass criteria fm audio l/r imbalance should be no more than 1 db.
AN603 rev. 0.3 11 3.9. fm tuning indicator sensitivity 3.9.1. description the test measures the needed rf input level to turn on the tuning indicator. 3.9.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. decrease signal generator rf level, until the tuning indicator turns off. 6. then increase signal generator rf level vrf0 from low to high unt il tuning indicator turns on. 7. fm tuning indicator sensitivity = vrf0. 3.9.3. pass criteria fm tuning indicator sensitivity should be no more than 15 db v.
AN603 12 rev. 0.3 3.10. fm stereo indicator sensitivity 3.10.1. description the test measures the needed rf input level to turn on the stereo indicator. 3.10.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select stereo modulation. i. set fm deviation = 22.5 khz. ii. set l = 1, r = 1. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. v. set pre-emphasis = 75 s. vi. set pilot = on. vii. set pilot deviation = 6.75 khz. d. enable modulation. e. enable carrier. 5. decrease signal generator rf level, until the stereo indicator turns off. 6. then increase signal generator rf level vrf0 from low to high until stereo indicator turns on. 7. fm stereo indicator sensitivity = vrf0. 3.10.3. pass criteria the fm stereo indicator sensitivity is determined by the value of blend mono , blend stereo, and blend separation. for the band property with mcu setting, the fm stereo in dicator sensitivity is the va lue which the user set (for setting the value of blend mono, blend stereo, and blend separati on in the setting menu, see si4840/44-demo board user?s guide for details), the error is 2 db v. for the band property with tuner default, the pass criteria are as follows: ?? fm stereo indicator sensit ivity should be 18~22 db v for bands with fm stereo indicator threshold of 6 db separation at 20 db v rf input. ?? fm stereo indicator sensitivity should be 26~30 db v for bands with fm stereo indicator threshold of 12 db separation at 28 db v rf input.
AN603 rev. 0.3 13 3.11. fm mono distortion 3.11.1. description the test measures thd in fm mono mode with a fixed, moderate input signal strength. 3.11.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd. i. set measurement mode = all di (all harmonics). ii. select unit = %. 4. configure generator: a. set carrier frequency = 98 mhz. b. select fm modulation. i. set fm deviation = 75 khz. ii. set rf level = 60 db v. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. c. enable modulation. d. enable carrier. 5. a djust volume control wheel to get audio output level rms = ?20 dbv. 6. record thd (%). 3.11.3. pass criteria fm mono distortion should be no more than 0.5%.
AN603 14 rev. 0.3 3.12. fm mono snr 3.12.1. description the test measures signal to noise ratio in fm mono mode at a fixed, moderate input signal strength. 3.12.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = noise. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record snr (db) = noise (db). 3.12.3. pass criteria fm snr should be more than 55 db.
AN603 rev. 0.3 15 3.13. fm radio am suppression 3.13.1. description the test quantifies undesired am suppression by measuring t he difference at the audio output between an fm and am modulated input signals. 3.13.2. conditi ons / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record the audio level, vaudio 0 . 6. turn off generator fm modulation. 7. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select am modulation. i. set depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 8. record the audio level, vaudio 1 . 9. am suppression (db) = vaudio 0 ? vaudio 1 3.13.3. pass criteria: fm radio am suppression should be more than 40 db.
AN603 16 rev. 0.3 3.14. fm audio output voltage 3.14.1. description the test measures fm audio volume level at an rf level of 60 db vemf. 3.14.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. test the audio voltage at fm tuner audio output pin lout or rout. 3.14.3. pass criteria fm audio output voltage level should range from 72 to 90 mvrms.
AN603 rev. 0.3 17 3.15. fm adjacent channe l selectivity (200 khz) 3.15.1. description the test quantifies receiver vulnerability to adjacent-channel signals at offset 200 khz from desired signal. this is a data sheet specification, two signal generators and one power combiner are used in the test. 3.15.2. conditions / procedure 1. connect test equipment as shown in figure 2. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator #1: a. set carrier frequency = 98 mhz. b. set rf level vrf 0 = 40 db v . c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record the audio level, vaudio 0 . 6. disable generator modulation. 7. configure generator #2: a. set carrier frequency = 98.2 mhz. (adjacent channel +200 k) b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 8. adjust generator #2 rf level*, vrf 1 , until the audio level, vaudio 1 = vaudio 0 ? 30 db. 9. selectivity adjacent channel +200 k (db) = vrf 1 ? vrf 0 . 10. configure generator #2: a. set carrier frequency = 97.8 mhz. (adjacent channel ?200 k) b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation.
AN603 18 rev. 0.3 e. enable carrier. 11. adjust generato r #2 rf level*, vrf 2 , until the audio level, vaudio 1 = vaudio 0 ? 30 db. 12. selectivity adjacent channel ?200 k (db) = vrf 2 ? vrf 0 . 13. selectivity adjacent channel 200 k = minimum (vrf 1 ? vrf 0 , vrf 2 ? vrf 0 ) note: generator #1 rf level is set to 40 db v to be able to get selectivity results gr eater than 60 db. this is not a limitation of the fm tuner or the evaluation board. maximum rf level setting for the r&s sml01 signal generator is 120 db v. you cannot increase the rf level beyond this value, so if vrf0 = 60 db v, selectivity numbers would be limited to 60 db. 3.15.3. pass criteria fm adjacent channel selectivity should be more than 50 db. 3.16. fm alternate chan nel selectivity (400 khz) 3.16.1. description the test quantifies receiver vulnerability to alternate-c hannel signals at offset 400 khz from desired signal. this setting is a data sheet specification, two signal generat ors and one power combiner are used in the test. 3.16.2. conditions / procedure 1. connect test equipment as shown in figure 2. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator #1: a. set carrier frequency = 98 mhz. b. set rf level vrf 0 = 40 db v . c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 5. record the audio level, vaudio 0 . 6. disable generator modulation. 7. configure generator #2: a. set carrier frequency = 98.4 mhz (alternate channel +400 k) b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 8. adjust generator #2 rf level*, vrf 1 , until the audio level, vaudio 1 = vaudio 0 ? 30 db.
AN603 rev. 0.3 19 9. selectivity alternate channel +400 k (db) = vrf 1 ? vrf 0 . 10. configure generator #2: a. set carrier frequency = 97.6 mhz (alternate channel ?400 k) b. set rf level = 60 db v. c. select fm modulation. i. set fm deviation = 22.5 khz. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable modulation. e. enable carrier. 11. adjust generato r #2 rf level*, vrf 2 , until the audio level, vaudio 1 = vaudio 0 ? 30 db. 12. selectivity alternate channel ?400 k (db) = vrf 2 ? vrf 0 . 13. selectivity alternate channel 400 k = minimum (vrf 1 ? vrf 0 , vrf 2 ? vrf 0 ). note: generator #1 rf level is set to 40 db v to be able to get selectiv ity results greater than 60 db. this is not a limitation of the fm tuner or the evaluation board. maximum rf level setting for the r&s sml01 signal generator is 120 db v. you cannot increase the rf level beyond this value, so if vrf0 = 60 db v, selectivity numbers would be limited to 60 db. 3.16.3. pass criteria fm alternate channel selectivit y should be more than 60 db.
AN603 20 rev. 0.3 3.17. fm stereo pilot rejection 3.17.1. description stereo pilot rejection is the quality criterion of a tuner that is measured as the ratio of wanted audio frequency voltage to pilot frequency voltage according to the equation: 3.17.2. conditions / procedure 1. connect test equipment as shown in figure 1. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator: a. set carrier frequency = 98 mhz. b. set rf level = 60 db v. c. select stereo modulation. i. set fm deviation = 67.5 khz. ii. set l = 1, r = 1. iii. set source = lfgen. iv. set lfgen frequency = 1 khz. v. set pre-emphasis = 75 s. vi. set pilot = on. vii. .set pilot deviation = 6.75 khz. d. enable modulation. e. enable carrier. 5. adjust volume control wheel to get audio output level rms = ?20 dbv. 6. audio 1 khz level (dbv) = v1 khz. 7. disable 1 khz tone (by disabling 1 khz source, not stereo mod) 8. configure audio analyzer frequency mode = fix: 19 khz. 9. audio 19 khz level (dbv) = v19 khz. 10. pilot rejection (relative to pilot) (db) = v1 khz ? v19 khz + 20*log10 ( ? pilot/ ? f) = v1 khz ? v19 khz ? 20. 3.17.3. pass criteria fm stereo pilot rejection should be more than 40 db. pilot rejection vaudio0 (1 khz) 20 ? pilot ? f ? ?? log ? vaudio0 19 khz ?? where ? f is fm frequency deviation and ? pilot is pilot frequency deviation. ? + =
AN603 rev. 0.3 21 4. am/sw tuner testing setup 4.1. am/sw common setup am tuner standard configuration ?? tune tuner exactly to am frequency = 1000 khz. se e the si4822/26/27/40/44-demo board user?s guide for details. ?? set rf level at the antenna input 74 db vemf. ?? set volume set to maximum unless otherwise specified. ?? cable length between the generator and antenna input should be as short as possible. sw tuner standard configuration ?? tune tuner exactly to sw frequency = 11.85 mhz. se e the si4822/26/27/40/44-de mo board user?s guide for details. ?? set rf level at the antenna input 74 db vemf. ?? set volume to maximum unless otherwise specified. ?? connect sg to the antenna input through an antenn a dummy (10 pf cap in series). the cable length between the generator and antenna input should be as short as possible. figure 3. am tuner setup with one generator �������� �
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AN603 24 rev. 0.3 am/sw tuner test equipment list: ?? rohde & schwarz upl audio analyzer ?? rohde &schwarz sml01 signal generator ?? mini-circuits power combiner ?? sw antenna dummy figure 8. sw antenna dummy circuit 4.2. am/sw tuner testing considerations several issues must be considered to make accura te measurements. first, the power combiner and cable lo sses must be calibrated and factored into each measurement. the loss for the mini-circuit power comb iner is approximately 6 db. second, most signal generators display the voltage genera ted at the input of the device under test (dut) assuming an input resistance of 50 ? . for example, if the signal generator displays vl = 1 v (0 db v), the generator source voltage vs is 2 v (6 db v). the load voltage vl is generated from the source voltage vs by the voltage divider created by the 50 ? generator source resistance rs and the 50 ? load resistance rl. this distinction is important only for sensitivity, which is specified in v emf*, where emf refers to the source voltage vs. measurements such as am suppression, selectivity, and spurious response are relative and may be referenced using vs or vl. to summarize, the generator displays the voltage at the in put of the dut. input impedan ce for the si4822/26/27/40/44 am/sw tuner is high, so to convert the value displayed on the signal generator to emf, double the voltage (add 6db) for sw testing, connect the sg to the antenna input thr ough an antenna dummy to simulate the characteristics of a normal whip antenna at sw frequency band.
AN603 rev. 0.3 25 5. am/sw testing procedure 5.1. am/sw tuning frequency range 5.1.1. description the test checks the lowest possible tuning frequency and th e highest possible tuning frequency of a selected band on the si4822/26/27/40/44 am/sw receiver. 5.1.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. iv. set rf level = 20 db v. b. enable am modulation. c. enable rf carrier. 5. slide band switch or press push button to select am1/sw1 band for testing. 6. turn tuning wheel to th e lowest possible position. 7. adjust signal generator rf (by 10 khz step), un til the measured sinad reaches maximum level. record this rf frequency as the lowest tuning frequency fmin. 8. repeat for highest tuning frequency point fmax. 9. repeat for other am/sw band testing.
AN603 26 rev. 0.3 5.1.3. pass criteria for the band property with mcu setting, the tuning frequency range is the range which t he user set (for setting the value of band top and band bottom in the setting menu, see the si4822/26/27/40/44-demo board user?s guide for details). for the band property with tuner default, the pass criteria are as follows: table 2. am frequency range parameter min max unit am1 frequency range 520 1710 khz am2 frequency range 522 1620 khz am3 frequency range 504 1665 khz am4 frequency range 520 1730 khz am5 frequency range 510 1750 khz table 3. sw frequency range parameter min max unit sw1 frequency range 5.6 6.4 mhz sw2 frequency range 5.95 6.2 mhz sw3 frequency range 6.8 7.6 mhz sw4 frequency range 7.1 7.6 mhz sw5 frequency range 9.2 10.0 mhz sw6 frequency range 9.2 9.9 mhz sw7 frequency range 11.45 12.25 mhz sw8 frequency range 11.6 12.2 mhz sw9 frequency range 13.4 14.2 mhz sw10 frequency range 13.57 13.87 mhz sw11 frequency range 15.0 15.9 mhz sw12 frequency range 15.1 15.8 mhz sw13 frequency range 17.1 18.0 mhz sw14 frequency range 17.48 17.9 mhz sw15 frequency range 21.2 22.0 mhz sw16 frequency range 21.45 21.85 mhz
AN603 rev. 0.3 27 5.2. am/sw sensitivity 5.2.1. description sensitivity is the rf level in db vemf at the input of the antenna at which audio sinad equals 26 db. 5.2.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable am modulation. d. enable rf carrier. 5. adjust genera tor rf level vrf 0 , until audio analyzer sinad = 26 db 1 db. 6. sensitivity (db v) = vrf0. 5.2.3. pass criteria am/sw sensitivity should be no more than 33 db vemf.
AN603 28 rev. 0.3 5.3. am sensit ivity ? radiation 5.3.1. description sensitivity is the rf level in db vemf at the input of the standard am loop antenna connected to signal generator, when the demo board output audio sinad equals 26 db. 5.3.2. conditions / procedure 1. connect test equipment as shown in figure 5. 2. configure the tuner in standard configuration, and this test must be conducted inside a shielded room. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable am modulation. d. enable rf carrier. 5. adjust genera tor rf level, vrf 0 , until audio analyzer sinad = 26 db 1 db. 6. sensitivity (db v) = vrf 0 . note: tx antenna is the standard am loop antenna; rx antenna is the ferrite loop stick ant enna mounted on the si4822/26/27/ 40/44-demo board or air loop antenna that can be connecte d to the demo board. the distance between tx antenna and rx antenna is 60 cm, center to center. 5.3.3. pass criteria am radiation sensitivity should be no more than 78 db vemf.
AN603 rev. 0.3 29 5.4. am/sw image rejection 5.4.1. description the test measures the am/sw image rejection of the tuner. 5.4.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable am modulation. d. enable rf carrier. 5. adjust generator rf level, vrf1, until audio analyzer sinad = 26 db 1 db. 6. record the rf level = vrf1. 7. change generator carrier frequency to 1090 khz. (11.76 mhz for shortwave) 8. adjust generator rf le vel*, vrf2, until audio analyzer sinad = 26 db 1 db. 9. record the rf level = vrf2. 10. image rejection (db) = vrf2 ? vrf1. note: maximum rf level setting for the r&s sml01 signal generator is 120 db v. you cannot increase the rf level beyond this value. if you adjust the generat or rf level from vrf1 to 120 db v, the audio analyzer sinad still can not get to the sinad = 26 db 1 db and your image rejection will be better than 120 db v ? vrf1. 5.4.3. pass criteria am/sw image rejection should be no less than 60 db.
AN603 30 rev. 0.3 5.5. am/sw selectivity ?6 db 5.5.1. description the test measures the am/sw frequency range when audio output level drops by 6 db. 5.5.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. enable am modulation. d. enable rf carrier. 5. adjust genera tor rf level vrf 1 , until audio analyzer sinad = 26 db 1 db. 6. record the audio output level (dbv) = vaudio0 7. raise the signal generator rf frequency fh, until audio output level vaudio1 = vaudio0-6. 8. lower the signal generator rf frequency fl, until audio output level vaudio1 = vaudio0-6. 9. selectivity ?6 db (khz) = fh ? fl. 5.5.3. pass criteria am/sw selectivity ?6 db should be no more than 35 khz.
AN603 rev. 0.3 31 5.6. am/sw adjacent channel selectivity 5.6.1. description the test measures am/sw receiver susc eptibility to blockers at adjacent channel (10 khz or 9 khz). two signal generators and one power combiner are used in the test. 5.6.2. conditions / procedure 1. connect test equipment as shown in figure 4 or figure 7. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator #1: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. set rf level vrf 0 = 40 db v. 1 c. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable am modulation. e. enable rf carrier. 5. record the audio level, vaudio 0 . 6. disable generator modulation. 7. configure generator #2: a. set carrier frequency = 1010 khz (adjacent channel +10 k) 2,3,4 b. set rf level = 50 db v. c. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable am modulation. e. enable rf carrier. 8. adjust generator #2 rf level*, vrf 1 , until the audio level, vaudio 1 = vaudio 0 ? 30 db. 9. selectivity adjacent channel +10 k (db) = vrf 1 ? vrf 0 . 10. configure generator #2: a. set carrier frequency = 990 khz (adjacent channel ?10 k) 2,3,4 b. set rf level = 50 db v. c. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable am modulation.
AN603 32 rev. 0.3 e. enable rf carrier. 11. adjust generato r #2 rf level*, vrf 2 , until the audio level, vaudio 1 = vaudio 0 ? 30 db. 12. selectivity adjacent channel ?10 k (db) = vrf 2 ? vrf 0 . 13. selectivity adjacent channel 10 k = minimum (vrf 1 ? vrf 0 , vrf 2 ? vrf 0 ) notes: 1. generator #1 rf level is set to 40 db v to be able to get selectivity results greater than 60 db. this is not a limitation of the fm tuner or the evaluation board. maximum rf level setting for the r&s sml01 signal generator is 120 db v. you cannot increase the rf level beyond this value, so if vrf0 = 60 db v, selectivity numbers would be limited to 60 db. 2. for shortwave, the adjacent channel is defined as rf 10 k. 3. for the am band with 10 khz channel space, t he adjacent channel will be 10 khz away (rf 10 k). 4. for the am band with 9 khz channel space, th e adjacent channel will be 9 khz away (rf9 k). 5.6.3. pass criteria am adjacent channel selectiv ity 10 khz (or 9 khz) shou ld be no less than 52 db. sw adjacent channel selectivity 10 khz should be no less than 35 db. 5.7. am/sw audio frequency response 5.7.1. description audio frequency response is the measure of linearity of ou tput voltage vs. modulation frequency across the audio band. 5.7.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = rms select. i. set bandwidth = bp 3%. ii. set units = dbv. iii. set frequency mode = fix: 1 khz. 4. configure generator #1: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. set rf level vrf 0 = 74 db vemf c. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. d. enable am modulation. e. enable rf carrier. 5. audio 1 khz level (dbv) = v 1khz. 6. configure audio analyzer frequency mode thr ough rms select function. set frequency mode = fix: 50 hz. 7. configure generator lfgen frequency = 50 hz. 8. audio 50 hz level (dbv) = v 50hz . 9. configure audio analyzer frequency mode thr ough rms select function. set frequency mode = fix: 3khz. 10. configure generator lfgen frequency = 3 khz. 11. audio 3 khz level (dbv) = v3 khz. 12. audio frequency response (db) equals the greater magnitude of (v 50hz ? v 1khz ) and (v 3khz ? v 1khz ).
AN603 rev. 0.3 33 5.7.3. pass criteria the greater magnitude of (v50 hz ? v 1khz) and (v3 khz ? v 1khz) should be no more than 20 db. 5.8. am/sw thd 5.8.1. description the test measures am/sw thd at an rf level of 74 db vemf. 5.8.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd. i. set measurement mode = all di (all harmonics). ii. set unit = %. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. record thd (%). 5.8.3. pass criteria am/sw thd should be no more than 0.5%.
AN603 34 rev. 0.3 5.9. am/sw thd at high modulation depth 5.9.1. description the test measures am/sw th d at 90% modulation depth. 5.9.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd. i. set measurement mode = all di (all harmonics). ii. set unit = %. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 90%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. adjust volume control wheel to get audio output level rms = ?14 dbv. 6. record thd (%). 5.9.3. pass criteria am/sw thd at high modulation depth should be no more than 0.5%.
AN603 rev. 0.3 35 5.10. am/sw audio output voltage 5.10.1. description the test measures am/sw audio volume level at an rf level of 74 db vemf. 5.10.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. test the audio voltage at fm tuner audio output pin lout or rout. 5.10.3. pass criteria tuner am/sw audio output level is between 54 and 67 mvrms.
AN603 36 rev. 0.3 5.11. am/sw audio snr 5.11.1. description the test measures am/sw snr performance with a desired signal with rf level of 74 db vemf. 5.11.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = noise. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. record snr (db) = noise (db). 5.11.3. pass criteria am/sw snr should be no less than 52 db.
AN603 rev. 0.3 37 5.12. am/sw sinad 5.12.1. description the test measures am sinad with the desired signal at an rf level of 74 db vemf. 5.12.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. record sinad (db) = sinad (db). 5.12.3. pass criteria am/sw sinad should be more than 50 db.
AN603 38 rev. 0.3 5.13. am/sw sinad at high modulation depth 5.13.1. description the test measures am/sw sinad with the desired signal at an rf level of 74 db vemf and modulation depth of 90%. 5.13.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 90%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 74 db vemf. d. enable am modulation. e. enable rf carrier. 5. adjust volume control wheel to get audio output level rms = ?14 dbv. 6. record sinad (db) = sinad (db). 5.13.3. pass criteria am/sw sinad at high modulation depth should be more than 40 db.
AN603 rev. 0.3 39 5.14. am/sw tuning indicator sensitivity 5.14.1. description the am/sw tuning indicator sensitivity test measures the needed rf input level to turn on the tuning indicator. 5.14.2. conditions / procedure 1. connect test equipment as shown in figure 3 or figure 6. 2. configure the tuner in standard configuration. 3. configure the audio analyzer: a. select analyze. b. set function = thd+n / sinad. i. set measurement mode = sinad. ii. set unit = db. iii. set filter = a-weighting. iv. set frequency limit low = 300 hz. v. set frequency limit high = 15000 hz. 4. configure generator: a. set carrier frequency = 1000 khz. (11.85 mhz for shortwave) b. select am modulation. i. set am modulation depth = 30%. ii. set source = lfgen. iii. set lfgen frequency = 1 khz. c. set rf level = 60 db v. d. enable am modulation. e. enable rf carrier. 5. decrease signal generator rf level, until the tuning indicator turns off. 6. then increase signal generator rf level vrf0 from low to high until tuning indicator turns on. 7. tuning indicator sensitivity = vrf0. 5.14.3. pass criteria am tuning indicator sensitivit y should be no more than 22 db v. sw tuning indicator sensitivity should be no more than 20 db v.
AN603 40 rev. 0.3 d ocument c hange l ist revision 0.2 to revision 0.3 ? updated the title. ? updated figures 1-7. ? updated "1. introduction" ? updated "2. fm tuner testing setup" ? updated "3.1. fm tuning frequency range" ? updated "4. am/sw tuner testing setup" ? updated "5.1 am/sw tuning frequency range"
AN603 rev. 0.3 41 n otes :
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