1 / 42

Harmonic Distortion versus Frequency in Amplifiers

Harmonic Distortion versus Frequency in Amplifiers. By Jorge Vega – Characterization Engineer & Raj Ramanathan – Design Engineer Precision Analog – Linear products – Op Amps. Agenda. Introductory comments Measurement setup and THD+N Tool Blocks RMS calculation of THD+N

shaine-edwards
Download Presentation

Harmonic Distortion versus Frequency in Amplifiers

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Harmonic Distortion versus Frequency in Amplifiers By Jorge Vega – Characterization Engineer & Raj Ramanathan – Design Engineer Precision Analog – Linear products – Op Amps

  2. Agenda • Introductory comments • Measurement setup and THD+N • Tool Blocks • RMS calculation of THD+N • THD+N versus Frequency • Noise Dominated Region • THD Dominated Region • Slew Rate Induced Distortion • Summary

  3. Introductory Comments • What is harmonic distortion and why do we care?  non-linearity

  4. Introductory Comments • What is harmonic distortion and why do we care? •  non-linearity • Types of distortion • Understanding how noise, input source resistance, open loop gain, closed loop gain, slew rate, loading all affect distortion • OPA1652, OPA1662 and OPA1602  line of Sound Plus Audio Amplifiers. Very low distortion and noise amplifiers

  5. Measurement Tool and THD+NTool Blocks Tool of choice in industry: Audio Precision ~ 27k$ General tool blocks: • Pure Sine wave generator • Fundamental Notch Filter • Band Limiting filter • RMS detector • AC Voltmeter • DSP Processing •  Clean signal generator ~ -115dB distortion ~ 0.0001% •  Leaves only harmonics. Eliminates fundamental •  Filter settings 22kHz, 30 kHz, 80 kHz & 500 kHz •  Converts varying AC signals into rms equivalent •  Measurement of rms values •  FFT is generated 1 2 3 4 5 6

  6. Measurement Tool and THD+NTool Blocks Notched Fundamental illustration Harmonics Fundamental at 10 kHz Fundamental removed by notch filter

  7. Recognize RMS operation in THD+N RMS sum of THD+N Wideband noise THD Measurement Tool and THD+NRMS calculation of THD+N Key takeaway: Noise dominated region and THD dominated region • V1 Fundamental of the input signal • VN Harmonics • VNOISE Amplifier’s noise • Graphical representation of RMS equation • Shows THD+N measured with different fundamental frequencies applied • 100 Hz fundamental applied  THD+N = 0.00001% • 10 kHz fundamental applied  THD+N = 0.0001%

  8. Recognize RMS operation in THD+N RMS sum of THD+N Wideband noise THD Noise dominated THD dominated Measurement Tool and THD+NRMS calculation of THD+N

  9. THD+N versus Frequency Noise Dominated Region OPA1652 What is a typical configuration? • Buffer configuration • Measurement bandwidth set to 80kHz but 500kHz equally typical • Fixed 3Vrms amplitude sinusoid applied while sweeping frequency.

  10. THD+N versus Frequency Noise Dominated Region OPA1652 • Why is the Noise-dominated region typically lowest in THD+N values? • Spectral content dominated by the amplifier’s noise as opposed to its harmonics. • Without noise, the curve would continue to decrease with a slope of +20 dB/decade at low frequencies

  11. THD+N versus Frequency Noise Dominated Region OPA1652 Example 1 illustrates the relationship between noise and distortion. The objective will be to learn how to go back and forth from noise to THD+N and vice versa.

  12. OPA1652 Noise from datasheet • If we know the noise density in , what happens if we multiply by: ? • THD+N versus FrequencyNoise Dominated RegionExample 1 Add value to graph Keyword OPA1652  we get Vrms • Operation is the same as taking the area under the noise density curve. • It is an approximation since it does not account for the flicker noise region.

  13. V1 is the fundamental • THD+N versus FrequencyNoise Dominated RegionExample 1 • Now that we have Vrms how do we get to THD+N? • VN is zero because the harmonics are below the noise floor. So we end up with:

  14. OPA1652 Matches! ~0.00004% • THD+N versus FrequencyNoise Dominated RegionExample 1 Example 1 and BW = 80kHz , then where where VNOISE=1.27 uVRMS and V1 = 3 VRMS then,

  15. THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on Noise THD+N is affected by the source resistance:

  16. THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on Noise Gain is 1V/V Voltage noise intrinsic to the amplifier Current noise intrinsic to amplifier multiplied the source resistance Thermal noise of resistance

  17. OPA1662: Bipolar Amplifier OPA1652: CMOS Amplifier CMOS amplifier Constant & Dominant at Low R Dominates at High Rsource • THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on Noise delta is Bipolar amplifier Constant & Dominant at Low R Dominates at High Rsource

  18. OPA1662: Bipolar Amplifier OPA1652: CMOS Amplifier • THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on Noise • Quick questions: • If noise is the only care about: • What amplifier would you want to use if source resistance is less than 1kΩ? • What if the source resistance is ~ 6kΩ? • What effect does this have on THD+N?

  19. Bipolar Amplifier • THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on THD+N • Higher source resistance yields higher THD+N because of noise contribution • Finding THD+N from noise is similar to example 1

  20. 0.00005% • THD+N versus FrequencyNoise Dominated RegionSource Resistance effect on THD+N Example 2 where K = 1.38 E-23 J/K T=300K and RS=1kΩ, then Total integrated noise is obtained as in Example 1.

  21. THD+N versus FrequencyTHD Dominated RegionAol and Distortion • At high frequencies the amplifier becomes more non-linear and THD+N increases at 20dB per decade. • Region is dominated by THD and not noise. • Type of distortion is referred to as “gain roll-off induced distortion”

  22. THD+N versus FrequencyTHD Dominated RegionExample 3 : Find THD • How can we find THD at 10kHz? • Obtain a Fourier spectrum with 3 Vrms input signal set at 10kHz.

  23. THD+N versus FrequencyTHD Dominated RegionExample 3 : Find THD • Shows which harmonics are dominating • Shows if THD+N is noise or THD dominated • Used to validates THD+N results

  24. 0.000126% • THD+N versus FrequencyTHD Dominated RegionExample 3: Find THD where: V1 = 0 dB, V2 = –120.07 dB, V3 = –124.06 dB, and V4 = –135.26 dB. Amplitudes need to be converted to rms power values. Thus we have: • Shows that at 10kHz, measurement is THD • dominated. • What happens if add noise?

  25. Matches! 0.000126% • THD+N versus FrequencyTHD Dominated RegionExample 3: Find THD+N The noise magnitude is VNOISE = 0.42 uVrms, then THD+N is:

  26. Equation has two knobs: • . • Feedback factor • THD+N versus FrequencyTHD Dominated RegionAol and Distortion Open loop gain Closed loop gain Loop gain Feedback factor What happens to THD if we tweak Aol knob while leaving the feedback factor fixed at 1?

  27. THD+N versus FrequencyTHD Dominated RegionAol and Distortion Pole where • Large open-loop gain yields better correction by virtue of negative feedback than when open-loop gain is small. • Open-loop gain decreases with frequency at –20 dB per decade, the ability of negative feedback to correct for the amplifier’s inherent nonlinearities is degraded with increasing frequency. • THD increases with frequency because the amplifier has less open loop gain to correct for errors at the input

  28. THD+N versus Frequency RR Output Stage Load Induced Distortion R-to-R Output Stage • Open loop gain decreases with loading. • Output transistor may be trioding with heavy loads, at this point all linear bets are off. • Loss of Aol yields degradation of linearity

  29. THD+N versus FrequencyTHD Dominated RegionAol and Distortion Key Takeaway  Higher Aol at frequencies of interest is better for correcting non-linearities

  30. Equation has two knobs: • . • Feedback factor • THD+N versus FrequencyTHD Dominated RegionAol and Distortion Open loop gain Closed loop gain Loop gain Feedback factor What happens to THD+N if we tweak Beta knob while leaving the Aol fixed at 120dB?

  31. THD+N versus FrequencyTHD Dominated RegionClosed Loop Gain and Distortion • Lower closed loop gain yields higher Loop Gain • Good for distortion

  32. THD+N versus FrequencyTHD Dominated RegionClosed Loop Gain and Distortion • Distortion is 10x worse in a gain of 10V/V compared to gain 1V/V • THD worsens with closed loop gain because the amplifier has less loop gain to correct for errors at the input

  33. THD+N versus FrequencySlew Rate Induced Distortion • What happens if we keep going up in frequency? • Distortion grossly increases and reaches “Slew-rate induced” distortion • To see this we need to understand the relationship between fullpower bandwidth and slew rate.

  34. Then slew rate is: THD+N versus FrequencySlew Rate Induced Distortion Full Power Bandwidth and Slew Rate If the output signal is given by: 375kHz after deviating we have: where The maximum slew rate occurs when the cosine term is 1. Thus, we have: If SR = 10V/us and Vp = 4.24Vp then the max frequency is 375kHz So if the amplifier is fed a 3Vrms (same as 4.24Vp) signal, at a frequency of 375kHz the amplifier will be slew rate limited

  35. THD+N versus FrequencySlew Rate Induced Distortion • The amplifier’s negative feedback is not fast enough to keep up with the input. • Output cannot swing completely and gross degradation of linearity occurs.

  36. THD+N versus FrequencyPratical tips Practical Tips for low THD+N in your application design 1. Minimize the resistor value connected to the positive and negative inputs , it increases noise.

  37. THD+N versus FrequencyPratical tips Practical Tips for low THD+N in your application design 1. Minimize the resistor value connected to the positive and negative inputs , it increases noise. 2. Select amplifier with low THD, high Aol at frequencies of operation, and high slew rate. 3. Minimize gains. Lower closed-loop gain means higher loop gain 4. Reduce loading as much as possible on the amplifier, it hurts Aol.

  38. THD+N versus FrequencyPratical tips Practical Tips for low THD+N in your application design 1. Minimize the resistor value connected to the positive and negative inputs , it increases noise. 2. Select amplifier with low THD, high Aol at frequencies of operation, and high slew rate. 3. Minimize gains. Lower closed-loop gain means higher loop gain 4. Reduce loading as much as possible on the amplifier, it hurts Aol. • 5. Use power-supply bypass capacitors • Bulk caps 4.7uF to 10uF within 1 inch of power pins. • High frequency caps 10nF to 100nF within 0.1 inch of power pins. • Use mica if possible for high frequency.

  39. THD+N versus FrequencyPratical tips Practical Tips for low THD+N in your application design 1. Minimize the resistor value connected to the positive and negative inputs , it increases noise. 2. Select amplifier with low THD, high Aol at frequencies of operation, and high slew rate. 3. Minimize gains. Lower closed-loop gain means higher loop gain 4. Reduce loading as much as possible on the amplifier, it hurts Aol. • 5. Use power-supply bypass capacitors • Bulk caps 4.7uF to 10uF within 1 inch of power pins. • High frequency caps 10nF to 100nF within 0.1 inch of power pins. • Use mica if possible for high frequency. 6. Remove ground planes underneath amplifier and use minimum feedback resistor values so as to avoid effects of parasitic capacitance.

  40. Summary • Types of distortion: • Noise dominated distortion • Gain roll-off induced distortion • Slew induced distortion • Practical tips • Things to look forward to: • THD+N versus Amplitude plots and their significance • Measuring lower than -120dB (the Audio Precision’s noise floor) • Troubleshooting THD+N values with “reading channel” • 4. Effects of temperature on distortion: Thermal Distortion • Acknowledgements: • Art Kay, Bruce Trump, Randy Heilman • References: • Bob Metzler’s Audio Precision Measurement Handbook • James Karki’s Designing for low distortion with high speed opamps • Gray and Meyer

  41. THD+N versus Frequency Back up slides

  42. THD+N versus FrequencyTHD Dominated RegionClosed Loop Gain and Distortion • The closed loop equation for an op amp is given by: • The larger the open loop gain, the more ACL resembles 1/β. • The noise gain in an op amp, NG, is given by 1/β, so the equation can be rewritten as:: , then • The ratio of NG/AOL is an error term. • As the noise gain increases, the error term increases. The effect is that the amplifier distortion worsens because it has less loop gain to linearize the distortion error.

More Related