Dynamic range

From Wikipedia, the free encyclopedia

Dynamic range (abbreviated DR, DNR,[1] or DYR[2]) is the ratio between the largest and smallest values that a certain quantity can assume. It is often used in the context of signals, like sound and light. It is measured either as a ratio or as a base-10 (decibel) or base-2 (doublings, bits or stops) logarithmic value of the ratio between the largest and smallest signal values.[3]

Electronically reproduced audio and video is often processed to fit the original material with a wide dynamic range into a narrower recorded dynamic range that can more easily be stored and reproduced; this processing is called dynamic range compression.

Human perception[edit]

Power ratios and their equivalent decibels and stops (integer values in bold)
Factor (power) Decibels
(10×log10 power)
Stops
(log2 power)
1 0 0
2 3.01 1
3.16 5 1.66
4 6.02 2
5 6.99 2.32
8 9.03 3
10 10 3.32
16 12.0 4
20 13.0 4.32
31.6 15 4.98
32 15.1 5
50 17.0 5.64
100 20 6.64
1,000 30 9.97
1,024 30.1 10
10,000 40 13.3
100,000 50 16.6
1,000,000 60 19.9
1,048,576 60.2 20
100,000,000 80 26.6
1,073,741,824 90.3 30
10,000,000,000 100 33.2

The human senses of sight and hearing have a relatively high dynamic range. However, a human cannot perform these feats of perception at both extremes of the scale at the same time. The human eye takes time to adjust to different light levels, and its dynamic range in a given scene is actually quite limited due to optical glare. The instantaneous dynamic range of human audio perception is similarly subject to masking so that, for example, a whisper cannot be heard in loud surroundings.

A human is capable of hearing (and usefully discerning) anything from a quiet murmur in a soundproofed room to the loudest heavy metal concert. Such a difference can exceed 100 dB which represents a factor of 100,000 in amplitude and a factor 10,000,000,000 in power.[4][5] The dynamic range of human hearing is roughly 140 dB,[6][7] varying with frequency,[8] from the threshold of hearing (around −9 dB SPL[8][9][10] at 3 kHz) to the threshold of pain (from 120–140 dB SPL[11][12][13]). This wide dynamic range cannot be perceived all at once, however; the tensor tympani, stapedius muscle, and outer hair cells all act as mechanical dynamic range compressors to adjust the sensitivity of the ear to different ambient levels.[14]

A human can see objects in starlight[a] or in bright sunlight, even though on a moonless night objects receive one billionth (10−9) of the illumination they would on a bright sunny day; a dynamic range of 90 dB. Change of sensitivity is achieved in part through adjustments of the iris and slow chemical changes, which take some time.

In practice, it is difficult for humans to achieve the full dynamic experience using electronic equipment. For example, a good quality liquid-crystal display (LCD) has a dynamic range limited to around 1000:1,[b] and some of the latest CMOS image sensors now[when?] have measured dynamic ranges of about 23,000:1.[15][c] Paper reflectance can produce a dynamic range of about 100:1.[16] A professional video camera such as the Sony Digital Betacam achieves a dynamic range of greater than 90 dB in audio recording.[17]

Audio[edit]

Audio engineers use dynamic range to describe the ratio of the amplitude of the loudest possible undistorted signal to the noise floor, say of a microphone or loudspeaker.[18] Dynamic range is therefore the signal-to-noise ratio (SNR) for the case where the signal is the loudest possible for the system. For example, if the ceiling of a device is 5 V (rms) and the noise floor is 10 µV (rms) then the dynamic range is 500000:1, or 114 dB:

In digital audio theory the dynamic range is limited by quantization error. The maximum achievable dynamic range for a digital audio system with Q-bit uniform quantization is calculated as the ratio of the largest sine-wave rms to rms noise is:[19]

However, the usable dynamic range may be greater, as a properly dithered recording device can record signals well below the noise floor.

The 16-bit compact disc has a theoretical undithered dynamic range of about 96 dB;[20][d] however, the perceived dynamic range of 16-bit audio can be 120 dB or more with noise-shaped dither, taking advantage of the frequency response of the human ear.[21][22]

Digital audio with undithered 20-bit quantization is theoretically capable of 120 dB dynamic range, while 24-bit digital audio affords 144 dB dynamic range.[6] Most Digital audio workstations process audio with 32-bit floating-point representation which affords even higher dynamic range and so loss of dynamic range is no longer a concern in terms of digital audio processing. Dynamic range limitations typically result from improper gain staging, recording technique including ambient noise and intentional application of dynamic range compression.

Dynamic range in analog audio is the difference between low-level thermal noise in the electronic circuitry and high-level signal saturation resulting in increased distortion and, if pushed higher, clipping.[23] Multiple noise processes determine the noise floor of a system. Noise can be picked up from microphone self-noise, preamp noise, wiring and interconnection noise, media noise, etc.

Early 78 rpm phonograph discs had a dynamic range of up to 40 dB,[24] soon reduced to 30 dB and worse due to wear from repeated play. Vinyl microgroove phonograph records typically yield 55-65 dB, though the first play of the higher-fidelity outer rings can achieve a dynamic range of 70 dB.[25]

German magnetic tape in 1941 was reported to have had a dynamic range of 60 dB,[26] though modern day restoration experts of such tapes note 45-50 dB as the observed dynamic range.[27] Ampex tape recorders in the 1950s achieved 60 dB in practical usage,[26] In the 1960s, improvements in tape formulation processes resulted in 7 dB greater range,[28]: 158  and Ray Dolby developed the Dolby A-Type noise reduction system that increased low- and mid-frequency dynamic range on magnetic tape by 10 dB, and high-frequency by 15 dB, using companding (compression and expansion) of four frequency bands.[28]: 169  The peak of professional analog magnetic recording tape technology reached 90 dB dynamic range in the midband frequencies at 3% distortion, or about 80 dB in practical broadband applications.[28]: 158  The Dolby SR noise reduction system gave a 20 dB further increased range resulting in 110 dB in the midband frequencies at 3% distortion.[28]: 172 

Compact Cassette tape performance ranges from 50 to 56 dB depending on tape formulation, with type IV tape tapes giving the greatest dynamic range, and systems such as XDR, dbx and Dolby noise reduction system increasing it further. Specialized bias and record head improvements by Nakamichi and Tandberg combined with Dolby C noise reduction yielded 72 dB dynamic range for the cassette.[citation needed]

A dynamic microphone is able to withstand high sound intensity and can have a dynamic range of up to 140 dB. Condenser microphones are also rugged but their dynamic range may be limited by the overloading of their associated electronic circuitry.[29] Practical considerations of acceptable distortion levels in microphones combined with typical practices in a recording studio result in a useful dynamic range of 125 dB.[28]: 75 

In 1981, researchers at Ampex determined that a dynamic range of 118 dB on a dithered digital audio stream was necessary for subjective noise-free playback of music in quiet listening environments.[30]

Since the early 1990s, it has been recommended by several authorities, including the Audio Engineering Society, that measurements of dynamic range be made with an audio signal present, which is then filtered out in the noise floor measurement used in determining dynamic range.[31] This avoids questionable measurements based on the use of blank media, or muting circuits.

The term dynamic range may be confusing in audio production because it has two conflicting definitions, particularly in the understanding of the loudness war phenomenon.[32][33] Dynamic range may refer to micro-dynamics,[34][35][36] related to crest factor,[37][38] whereas the European Broadcasting Union, in EBU3342 Loudness Range, defines dynamic range as the difference between the quietest and loudest volume, a matter of macro-dynamics.[32][33][39][40][41][42]

Electronics[edit]

In electronics dynamic range is used in the following contexts:

  • Specifies the ratio of a maximum level of a parameter, such as power, current, voltage[43] or frequency, to the minimum detectable value of that parameter. (See Audio system measurements.)
  • In a transmission system, the ratio of the overload level (the maximum signal power that the system can tolerate without distortion of the signal) to the noise level of the system.
  • In digital systems or devices, the ratio of maximum and minimum signal levels required to maintain a specified bit error ratio.
  • Optimization of bit width of digital data path (according to the dynamic ranges of signal) can reduce the area, cost, and power consumption of digital circuits and systems while improving their performance. Optimal bit width for a digital data path is the smallest bit width that can satisfy the required signal-to-noise ratio and also avoid overflow.[44][45][46][47][48][verification needed]

In audio and electronics applications, the ratio involved is often large enough that it is converted to a logarithm and specified in decibels.[43]

Metrology[edit]

In metrology, such as when performed in support of science, engineering or manufacturing objectives, dynamic range refers to the range of values that can be measured by a sensor or metrology instrument. Often this dynamic range of measurement is limited at one end of the range by saturation of a sensing signal sensor or by physical limits that exist on the motion or other response capability of a mechanical indicator. The other end of the dynamic range of measurement is often limited by one or more sources of random noise or uncertainty in signal levels that may be described as defining the sensitivity of the sensor or metrology device. When digital sensors or sensor signal converters are a component of the sensor or metrology device, the dynamic range of measurement will be also related to the number of binary digits (bits) used in a digital numeric representation in which the measured value is linearly related to the digital number.[43] For example, a 12-bit digital sensor or converter can provide a dynamic range in which the ratio of the maximum measured value to the minimum measured value is up to 212 = 4096.

Metrology systems and devices may use several basic methods to increase their basic dynamic range. These methods include averaging and other forms of filtering, correction of receivers characteristics,[43] repetition of measurements, nonlinear transformations to avoid saturation, etc. In more advance forms of metrology, such as multiwavelength digital holography, interferometry measurements made at different scales (different wavelengths) can be combined to retain the same low-end resolution while extending the upper end of the dynamic range of measurement by orders of magnitude.

Music[edit]

In music, dynamic range describes the difference between the quietest and loudest volume of an instrument, part or piece of music.[49] In modern recording, this range is often limited through dynamic range compression, which allows for louder volume, but can make the recording sound less exciting or live.[50]

The dynamic range of music as normally perceived in a concert hall does not exceed 80 dB, and human speech is normally perceived over a range of about 40 dB.[28]: 4 

Photography[edit]

A scene demanding high dynamic range, taken with the Nikon D7000 digital camera, capable of 13.9 stops of dynamic range per DxOMark.[51] The unedited version of the digital photo is to the left, while the shadows have been pushed heavily in Photoshop to produce the final image on the right. The better the dynamic range of the camera, the more an exposure can be pushed without significantly increasing noise.

Photographers use dynamic range to describe the luminance range of a scene being photographed, or the limits of luminance range that a given digital camera or film can capture,[52] or the opacity range of developed film images, or the reflectance range of images on photographic papers.

The dynamic range of digital photography is comparable to the capabilities of photographic film[53] and both are comparable to the capabilities of the human eye.[54]

There are photographic techniques that support even higher dynamic range.

  • Graduated neutral density filters are used to decrease the dynamic range of scene luminance that can be captured on photographic film (or on the image sensor of a digital camera): The filter is positioned in front of the lens at the time the exposure is made; the top half is dark and the bottom half is clear. The dark area is placed over a scene's high-intensity region, such as the sky. The result is more even exposure in the focal plane, with increased detail in the shadows and low-light areas. Though this does not increase the fixed dynamic range available at the film or sensor, it stretches usable dynamic range in practice.[55]
  • High-dynamic-range imaging overcomes the limited dynamic range of the sensor by selectively combining multiple exposures of the same scene in order to retain detail in light and dark areas. Tone mapping maps the image differently in shadow and highlights in order to better distribute the lighting range across the image. The same approach has been used in chemical photography to capture an extremely wide dynamic range: A three-layer film with each underlying layer at one hundredth (10−2) the sensitivity of the next higher one has, for example, been used to record nuclear-weapons tests.[56]

Consumer-grade image file formats sometimes restrict dynamic range.[57] The most severe dynamic-range limitation in photography may not involve encoding, but rather reproduction to, say, a paper print or computer screen. In that case, not only local tone mapping but also dynamic range adjustment can be effective in revealing detail throughout light and dark areas: The principle is the same as that of dodging and burning (using different lengths of exposures in different areas when making a photographic print) in the chemical darkroom. The principle is also similar to gain riding or automatic level control in audio work, which serves to keep a signal audible in a noisy listening environment and to avoid peak levels that overload the reproducing equipment, or which are unnaturally or uncomfortably loud.

If a camera sensor is incapable of recording the full dynamic range of a scene, high-dynamic-range (HDR) techniques may be used in postprocessing, which generally involve combining multiple exposures using software.

Dynamic ranges of common devices
Device Stops Contrast ratio
Glossy photograph paper 7 (7–7+23)[58] 128:1
LCD 9.5 (9-11)[59] 700:1 (500:1 – 2000:1)
Typical cellphone camera ~10[60][failed verification] varies
Negative film (Kodak VISION3) 13[61] 8000:1
Human eye 10–14[54] 1000:1 – 16000:1
OLED or quantum dot 13.2-20.9[62] 9500:1 – 2000000:1
High-end DSLR camera (Nikon D850) 14.8[63] 28500:1
Digital cinema camera (Red Weapon 8k) > 16.5[64] 92000:1

See also[edit]

Notes[edit]

  1. ^ Colour differentiation is reduced at low light levels.
  2. ^ Commercially the dynamic range is often called the contrast ratio meaning the full-on to full-off luminance ratio.
  3. ^ Reported as 14.5 stops, or doublings, equivalent to binary digits.
  4. ^ The 96 dB figure is for a triangle or sine wave. Dynamic range is 98 dB for sine wave[19] (see Quantization noise model).

References[edit]

  1. ^ ISSCC Glossary http://ieeexplore.ieee.org/iel5/4242240/4242241/04242527.pdf
  2. ^ "Archived copy" (PDF). Archived (PDF) from the original on 2015-04-11. Retrieved 2016-08-11.{{cite web}}: CS1 maint: archived copy as title (link), "Archived copy" (PDF). Archived (PDF) from the original on 2016-08-22. Retrieved 2016-08-11.{{cite web}}: CS1 maint: archived copy as title (link), "The data aquisition method of the Sussex MK4 EIM system" (PDF). 24 April 2014. Archived (PDF) from the original on 2016-08-27. Retrieved 2016-08-11.
  3. ^ "Dynamic range", Electropedia, IEC, archived from the original on 2015-04-26
  4. ^ D. R. Campbell. "Aspects of Human Hearing" (PDF). Archived from the original (PDF) on 2011-08-21. Retrieved 2011-04-21. The dynamic range of human hearing is [approximately] 120 dB
  5. ^ "Sensitivity of Human Ear". Archived from the original on 2011-06-04. Retrieved 2011-04-21. The practical dynamic range could be said to be from the threshold of hearing to the threshold of pain [130 dB]
  6. ^ a b Huber, David Miles; Runstein, Robert E. (2009). Modern Recording Techniques (7 ed.). Focal Press. p. 513. ISBN 978-0-240-81069-0. Archived from the original on 2017-11-20. the overall dynamic range of human hearing roughly encompasses a full 140 dB
  7. ^ "Occupational Noise Exposure, CDC DHHS (NIOSH) Publication Number 98-126". 1998. doi:10.26616/NIOSHPUB98126. Archived from the original on 2017-07-13. {{cite journal}}: Cite journal requires |journal= (help)
  8. ^ a b Montgomery, Christopher. "24/192 Music Downloads ...and why they make no sense". xiph.org. Archived from the original on 2020-04-26. Retrieved 2022-05-10. The very quietest perceptible sound is about -8dbSPL
  9. ^ Jones, Pete R (November 20, 2014). "What's the quietest sound a human can hear?" (PDF). University College London. Archived (PDF) from the original on March 24, 2016. Retrieved 2016-03-16. On the other hand, you can also see in Figure 1 that our hearing is slightly more sensitive to frequencies just above 1 kHz, where thresholds can be as low as −9 dB SPL!
  10. ^ Feilding, Charles. "Lecture 007 Hearing II". College of Santa Fe Auditory Theory. Archived from the original on 2016-05-07. Retrieved 2016-03-17. The peak sensitivities shown in this figure are equivalent to a sound pressure amplitude in the sound wave of 10 μPa or: about -6 dB (SPL). Note that this is for monaural listening to a sound presented at the front of the listener. For sounds presented on the listening side of the head there is a rise in peak sensitivity of about 6 dB [−12 dB SPL] due to the increase in pressure caused by reflection from the head.
  11. ^ Newman, Edwin B. (1972-01-01). "Speech and Hearing". American Institute of Physics handbook. New York: McGraw-Hill. pp. 3–155. ISBN 978-0070014855. OCLC 484327. The upper limit for a tolerable intensity of sound rises substantially with increasing habituation. Moreover, a variety of subjective effects are reported, such as discomfort, tickle, pressure, and pain, each at a slightly different level. As a simple engineering estimate it can be said that naive listeners reach a limit at about 125 dB SPL and experienced listeners at 135 to 140 dB.
  12. ^ Nave, Carl R. (2006). "Threshold of Pain". HyperPhysics. SciLinks. Archived from the original on 2009-07-06. Retrieved 2009-06-16. A nominal figure for the threshold of pain is 130 decibels ... Some sources quote 120 dB as the pain threshold
  13. ^ Franks, John R.; Stephenson, Mark R.; Merry, Carol J., eds. (June 1996). Preventing Occupational Hearing Loss - A Practical Guide (PDF). National Institute for Occupational Safety and Health. p. 88. Archived (PDF) from the original on 2009-04-23. Retrieved 2009-07-15. the threshold for pain is between 120 and 140 dB SPL.
  14. ^ "How The Ear Works". www.soundonsound.com. Archived from the original on 2015-06-06. Retrieved 2016-03-18.
  15. ^ "DXOmark Sensor Ranking". Archived from the original on 2010-05-05. Retrieved 2015-06-12.
  16. ^ "Dynamic Range in Digital Photography". Archived from the original on 2011-07-17. Retrieved 2011-07-11.
  17. ^ "Sony Product Detail Page MSWM2100/1". Sony Pro. Archived from the original on 2012-02-29. Retrieved 2011-12-30.
  18. ^ Ballou Glen M., Handbook for Sound Engineers, 3rd edition, Focal Press 2002, pp. 1107-1108
  19. ^ a b Bernd Seeber (1998). Handbook of applied superconductivity. CRC Press. pp. 1861–1862. ISBN 978-0-7503-0377-4. Archived from the original on 2017-11-20.
  20. ^ Fries, Bruce; Marty Fries (2005). Digital Audio Essentials. O'Reilly Media. p. 147. ISBN 978-0-596-00856-7. Archived from the original on 2017-01-09. Digital audio at 16-bit resolution has a theoretical dynamic range of 96 dB, but the actual dynamic range is usually lower because of overhead from filters that are built into most audio systems." ... "Audio CDs achieve about a 90-dB signal-to-noise ratio.
  21. ^ Montgomery, Chris (March 25, 2012). "24/192 Music Downloads ...and why they make no sense". xiph.org. Archived from the original on 7 July 2013. Retrieved 26 May 2013. With use of shaped dither, which moves quantization noise energy into frequencies where it's harder to hear, the effective dynamic range of 16 bit audio reaches 120dB in practice, more than fifteen times deeper than the 96dB claim. 120dB is greater than the difference between a mosquito somewhere in the same room and a jackhammer a foot away.... or the difference between a deserted 'soundproof' room and a sound loud enough to cause hearing damage in seconds. 16 bits is enough to store all we can hear, and will be enough forever.
  22. ^ Stuart, J. Robert (1997). "Coding High Quality Digital Audio" (PDF). Meridian Audio Ltd. Archived from the original (PDF) on 2016-04-07. Retrieved 2016-02-25. One of the great discoveries in PCM was that, by adding a small random noise (that we call dither) the truncation effect can disappear. Even more important was the realisation that there is a right sort of random noise to add, and that when the right dither is used, the resolution of the digital system becomes infinite.
  23. ^ Huber, Runstein 2009, pp. 416, 487 Archived 2017-11-20 at the Wayback Machine
  24. ^ Audio Engineering Society. E-Library. Jerry B. Minter. April 1956. Recent Developments in Precision Master Recording Lathes Archived 2008-12-11 at the Wayback Machine
  25. ^ Day, Timothy (2002). A Century of Recorded Music: Listening to Musical History. Yale University Press. p. 23. ISBN 978-0-300-09401-5. Archived from the original on 2017-11-20.
  26. ^ a b Daniel, Eric D.; C. Denis Mee; Mark H. Clark (1998). Magnetic Recording: The First 100 Years. Wiley-IEEE Press. p. 64. ISBN 978-0-7803-4709-0.
  27. ^ Richard L. Hess (July–August 2001), The Jack Mullin//Bill Palmer tape restoration project (PDF), Audio Engineering Society, archived from the original (PDF) on 2008-12-01
  28. ^ a b c d e f John Eargle (2005). Handbook of Recording Engineering. Springer Science & Business Media. ISBN 9780387284705.
  29. ^ Huber; Runstein (2010). Modern Recording Techniques. Taylor & Francis. p. 127. ISBN 9780240810690. Archived from the original on 2017-11-20.
  30. ^ Audio Engineering Society. E-Library. Louis D. Fielder. May 1981. Dynamic Range Requirement for Subjective Noise Free Reproduction of Music Archived 2008-12-11 at the Wayback Machine
  31. ^ AES-6id-2000
  32. ^ a b Deruty, Emmanuel (September 2011). "'Dynamic Range' & The Loudness War". Sound on Sound. Archived from the original on 2013-11-08. Retrieved 2013-10-24.
  33. ^ a b Emmanuel Deruty; Damien Tardieu (January 2014). "About Dynamic Processing in Mainstream Music". Journal of the Audio Engineering Society. 62 (1/2): 42–55. doi:10.17743/jaes.2014.0001.
  34. ^ Katz, Robert (2002). "9". Mastering Audio. Amsterdam: Boston. p. 109. ISBN 978-0-240-80545-0.
  35. ^ Ian Shepherd (2011-08-18). "Why the Loudness War hasn't reduced 'Loudness Range'". Archived from the original on 2014-02-09. Retrieved 2014-02-06.
  36. ^ Jason Victor Serinus. "Winning the Loudness Wars". Stereophile. Archived from the original on 2014-02-09. Retrieved 2014-02-06.
  37. ^ Earl Vickers (November 4, 2010). "The Loudness War: Background, Speculation and Recommendations" (PDF). AES 2010: Paper Sessions: Loudness and Dynamics. San Francisco: Audio Engineering Society. Archived (PDF) from the original on 2022-10-09. Retrieved July 14, 2011.
  38. ^ "Dynamic Range Meter". Archived from the original on 2014-10-27. Retrieved 2018-11-27.
  39. ^ Tech 3342 - Loudness Range: a Measure to Supplement EBU R 128 Loudness Normalization (PDF), European Broadcasting Union, archived (PDF) from the original on 2016-06-08, retrieved 2016-07-30
  40. ^ Serrà, J; Corral, A; Boguñá, M; Haro, M; Arcos, JL (26 July 2012). "Measuring the Evolution of Contemporary Western Popular Music". Scientific Reports. 2: 521. arXiv:1205.5651. Bibcode:2012NatSR...2E.521S. doi:10.1038/srep00521. PMC 3405292. PMID 22837813.
  41. ^ Hjortkjær, Jens; Walther-Hansen, Mads (2014). "Perceptual Effects of Dynamic Range Compression in Popular Music Recordings". Journal of the Audio Engineering Society. 62: 37–41. doi:10.17743/jaes.2014.0003.
  42. ^ Esben Skovenborg (April 2012). "Loudness Range (LRA) – Design and Evaluation". AES 132nd Convention. Archived from the original on 2014-10-25. Retrieved 2014-10-25.
  43. ^ a b c d Slyusar, Vadim I. (2004). "A method of investigation of the linear dynamic range of reception channels in a digital antenna array" (PDF). Radioelectronics and Communications Systems (Military Radioelectronic Technologies special issue). 47 (9): 20–25. doi:10.3103/S0735272704090043 (inactive 31 January 2024). Archived (PDF) from the original on 2016-02-05. Retrieved 2022-05-01.{{cite journal}}: CS1 maint: DOI inactive as of January 2024 (link)
  44. ^ Bin Wu; Jianwen Zhu; Najm, F.N. (2006). "Dynamic-range estimation". IEEE Transactions on Computer-Aided Design of Integrated Circuits and Systems. 25 (9): 1618–1636. arXiv:0802.3458. doi:10.1109/tcad.2005.859507. S2CID 11725031.
  45. ^ Wu, Bin; Zhu, Jianwen; Najm, Farid N. (2004). "An analytical approach for dynamic range estimation". Proceedings of the 41st annual conference on Design automation - DAC '04. p. 472. doi:10.1145/996566.996699. ISBN 1581138288. S2CID 8509478.
  46. ^ Bin Wu; Jianwen Zhu; Najm, F.N. (2004). "Dynamic range estimation for nonlinear systems". IEEE/ACM International Conference on Computer Aided Design, 2004. ICCAD-2004. pp. 660–667. doi:10.1109/iccad.2004.1382658. ISBN 0-7803-8702-3. S2CID 12949210.
  47. ^ Bin Wu; Jianwen Zhu; Najm, F.N. (2005). "A non-parametric approach for dynamic range estimation of nonlinear systems". Proceedings. 42nd Design Automation Conference, 2005. pp. 841–844. doi:10.1109/dac.2005.193932. ISBN 1-59593-058-2.
  48. ^ Wu, Bin (2012). "Dynamic range estimation for systems with control-flow structures". Thirteenth International Symposium on Quality Electronic Design (ISQED). pp. 370–377. doi:10.1109/isqed.2012.6187520. ISBN 978-1-4673-1036-9. S2CID 1045127.
  49. ^ Schmidt, J.C.; Rutledge, J.C. (1996). "Multichannel dynamic range compression for music signals". 1996 IEEE International Conference on Acoustics, Speech, and Signal Processing Conference Proceedings. Vol. 2. IEEE. pp. 1013–1016. doi:10.1109/ICASSP.1996.543295. ISBN 978-0-7803-3192-1. S2CID 5688882.
  50. ^ "The Death Of Dynamic Range". CD Mastering Services. Archived from the original on 2008-06-22. Retrieved 2008-07-17.
  51. ^ "Nikon D7000 : Tests and Reviews". DxO Labs. Retrieved December 30, 2017.
  52. ^ Karol Myszkowski; Rafal Mantiuk; Grzegorz Krawczyk (2008). High Dynamic Range Video. Morgan & Claypool Publishers. ISBN 978-1-59829-214-5. Archived from the original on 2014-01-08.
  53. ^ Michael Archambault (2015-05-26). "Film vs. Digital: A Comparison of the Advantages and Disadvantages". Archived from the original on 2016-06-17. Retrieved 2016-07-14.
  54. ^ a b "Dynamic Range in Digital Photography". PetaPixel. Archived from the original on 2016-07-08. Retrieved 2016-07-14.
  55. ^ Rob Sheppard (2006). The Magic of Digital Nature Photography. Sterling Publishing Company. ISBN 978-1-57990-773-0.
  56. ^ The Militarily Critical Technologies List Archived 2010-06-15 at the Wayback Machine (1998), pages II-5-100 and II-5-107.
  57. ^ "RAW vs. JPEG Overview". SLR Lounge. Archived from the original on 2016-08-17. Retrieved 2016-07-14.
  58. ^ "Paper grades". Retrieved November 9, 2019.
  59. ^ Terry Relph-Knight (July 16, 2018). "High Dynamic Range: The quest for greater image realism". ZD Net. Retrieved 2022-12-25.
  60. ^ "Of Phones, Pixels and Photons – why a 100 mp cell phone is not a GFX 100 - Luminous Landscape". 2021-04-27.
  61. ^ "Dynamic Range".[permanent dead link]
  62. ^ Brian Wagner (July 2, 2020). "HDR Nits are a Lie: It's Time to Embrace the Stop". Retrieved 2022-12-25.[self-published source?]
  63. ^ "Nikon D850 : Tests and Reviews". DxO Labs. Retrieved December 30, 2017.
  64. ^ "Red Weapon 8k Rating by DxOMark". 2017-01-10. Archived from the original on 2017-06-19.

External list[edit]