![\"Turbidity](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_instruments.jpg\")
Turbidity, as an optical property of water, is one of the more difficult parameters to measure. How murky or opaque water is can be a subjective measurement 1<\/sup>. Based on the measurement method, different units have been defined to standardize turbidity levels and allow comparisons. Today, there are three modern methods for measuring turbidity, and two for measuring total suspended solids. These methods have expanded the range and accuracy of turbidity measurements from basic object visibility tests and historical visual extinction methods 2<\/sup>. However, each method has its advantages and limitations.<\/p>\n Turbidity is caused by particles and colored material in water. It can be measured relative to water clarity, or directly with a turbidity instrument such as a turbidimeter or turbidity sensor. Turbidity sensors may also be referred to as submersible turbidimeters 28<\/sup>. Water clarity methods involve a secchi disc or tube. They are often quick and inexpensive, but are only as accurate as the person using them 1<\/sup>. Turbidity meters use nephelometry (90 degree scattering) or other optical scatter-detection techniques for fast, accurate turbidity measurements on water samples. Turbidity sensors also use optical technology, but instead of using sample cells, they can be placed directly in the water source to measure turbidity. In addition, turbidity sensors can be used for continuous turbidity measurements 21,22,23<\/sup>. However, when using a meter or a sensor, most turbidity data are not inter-comparable. Turbidity units such as NTU and FNU have \u201cno intrinsic physical, chemical or biological significance\u201d 52<\/sup>. Thus differences in suspended sediment type (e.g. algae, clay or sand) and differences in instrument design will alter a turbidity reading. These instruments can be convenient and accurate tools as long as consistency is maintained.<\/p>\n Total suspended solids (TSS) are the main cause of turbidity. The most common, and accurate, method of measuring suspended solids is by weight. To measure TSS, a water sample is filtered, dried, and weighed. This method is the most accurate technique for measuring total suspended solids, however it is also more difficult and time-consuming 3<\/sup>.<\/p>\n The second method is a recent development by the U. S. Geological Survey. This organization has developed a technique for calculating suspended sediment from acoustic Doppler meter backscatter 4<\/sup>. While this method is not as accurate as a weigh scale, it provides the opportunity for continuous suspended sediment measurements, just as turbidity sensors allow for continuous turbidity measurements. Total suspended solids can also be estimated from turbidity measurements, however, this requires linear regression modeling and must be re-calculated for each sampling period and location. No standard model exists due to the differences in stream flow, sediment concentration, and particle size 5<\/sup>. As mentioned above, turbidity units have no inherent value. They are a qualitative, rather than a quantitative, measurement 54<\/sup>. There is no standard conversion between various turbidity units (e.g. NTU or FNU) and quantitative mass measurements (mg\/L) 52<\/sup>. Furthermore, clear water is not always healthy, and likewise turbid water does not necessarily indicate an issue. Turbidity data must always be taken in context 54<\/sup>. This means that it is important to consider the nature of suspended solids that are present, in the larger picture of the water system (e.g. a stream, lake, ocean, or wastewater treatment plant). To this end, it is more often a change in turbidity that indicates an issue, such as the development of an algal bloom on a lake, or a steady increase in suspended sediment in a river due to a polluted tributary.<\/p>\n As a qualitative, contextual measurement, the variety of turbidity units in use can be confusing. Each measurement method uses a different unit. A multitude of turbidity units were introduced because a change in the type of light source, detector, or angle of measurement changes the turbidity reading. In addition, mineral-based solids will reflect more light, while organic particles tend to absorb more light 5<\/sup>. These effects are based on the relationship between light (wavelengths and beam width) and particle size, color and concentration 54<\/sup>. As such, different turbidity instruments can output various turbidity measurements even in the same sample 51<\/sup>.<\/p>\n While turbidity units can be approximately equal, to ensure accurate records, consistency in methods and instruments must be maintained. Historically, units such as NTU and JTU were often erroneously interchanged because they were assumed to be equivalent 55,56<\/sup>. Unfortunately, this practice still occurs today, particularly with FNU and NTU 57<\/sup>. Many instrument manuals suggest using inappropriate units simply because they are more well known. Which units should be used with which measurement method or instrument design can be found in the Quality Standards section.<\/p>\n If the use of a particular unit is absolutely necessary, correlations between two turbidity instruments can be developed 18<\/sup>. These calculated models can be used to convert between units and compare data from different instruments when using the same sample or same surface-water location 54<\/sup>. Likewise, correlations can also be made between suspended sediment concentrations and turbidity measurements 5<\/sup>. However, these calculated models are only adequate for the specific location where measurements were made. Surface waters are not static, and turbidity levels and sources will vary by location, season or other factors 51,54<\/sup>. Thus, in other bodies of water with changed particle type, size, and distribution, such conversions are no longer accurate 54<\/sup>. New measurements must be taken to calculate a new conversion model for that location.<\/p>\n Correlations between total suspended solids or suspended sediment concentrations in mg\/L and turbidity in turbidity units can be made with linear regression analysis, provided enough data is collected 5<\/sup>. In purely mineral-based samples, this relationship is expressed through the following equation 29<\/sup>:<\/p>\n When organic material, air bubbles or dissolved colored material is present, this equation can become inconsistent 29<\/sup>. In addition, the accuracy of the correlation is based on a linear relationship between turbidity and suspended solids 29<\/sup>. When the relationship becomes non-linear (above 40 NTU for nephelometric methods), the equation is no longer suitable. United States Geological Survey modeling uses streamflow data in addition to turbidity and suspended sediment measurements to calculate regression models. The USGS recommends using base-10 logarithmic transformation to meet linear regression assumptions 58<\/sup>. Transforming the data improves symmetry, linearity and normality, though it also requires a retransformation bias correction factor 58<\/sup>. An example of a linear regression model through this method may look like:<\/p>\n Once a regression model has been accepted, it can be used to predict suspended sediment concentrations 58<\/sup>. The model should be re-analyzed and validated as necessary, based on the nature of the surface-water source. If a single linear regression model does not meet established criteria, a multiple regression model can be used 58<\/sup>. Though no standardized formula exists, these calculated correlations can be useful in monitoring water quality 52<\/sup>. Care should be taken when when establishing relationships between turbidity and suspended sediment as the values of both in a body of water may constantly change 51<\/sup>.<\/p>\n <\/a><\/p>\n To further complicate turbidity measurements, there are several water quality standard methods and design standards in use. The United States Environmental Protection Agency has approved eight standards for monitoring drinking water 41<\/sup>. Until 2009, only four methods were accepted: USEPA Method 180.1, Standard Method 2130B, Great Lakes Instrument Method 2 (GLI 2) and Hach Method 10133 18<\/sup>. In 2009, the USEPA approved four new methods: Mitchell Methods M5271 and M5331, Orion AQ4500, and AMI Turbiwell 40<\/sup>.<\/p>\n The United States Geological Survey uses, but does not require, some EPA-approved methods, as non-regulatory methods can be more accurate at higher turbidity levels 18<\/sup>. Common USGS methods are: International Organization for Standardization (ISO) 7027, Standard Methods 2130B, USEPA Method 180.1, and GLI Method 2 6<\/sup>. The ADCP backscatter method is also gaining traction for monitoring total suspended solids specifically 4<\/sup>. However, when monitoring drinking water, the USGS states that EPA-approved methods must be followed 18<\/sup>.<\/p>\n Of all of these methods, the EPA Method 180.1 and the ISO 7027 are the most well-known guidelines and are internationally recognized when verifying turbidity meter and turbidity sensor performance and method compliance 14<\/sup>. Outside of the U.S., the ISO 7027 method is king 28<\/sup>. The American Society for Testing of Materials considers several of these methods as appropriate and recommends instruments utilizing the respective technologies based on turbidity level 19,20<\/sup>. However, ASTM D7315 is very specific about reporting procedures – units must indicate exactly which instrument design is being used 19,24<\/sup>.<\/p>\n Other instrument-based methods for measuring turbidity include: light attenuation, surface scatter, and backscatter 19<\/sup>. While turbidimeters and spectrophotometers using these designs exist, they do not comply with any of the above standards. To ensure accurate reporting when using a ratiometric turbidity meter or backscatter-based turbidity sensor, the ASTM D7315 unit reporting protocol should be referenced 24<\/sup>. Method 180.1, Determination of Turbidity by Nephelometry is the United States Environmental Protection Agency\u2019s standard for turbidity meter design. The standardized criteria attempt to ensure both accuracy and comparability between compliant meters 15<\/sup>. Instruments in compliance with the EPA Method 180.1 use Nephelometric Turbidity Units (NTU) 15<\/sup>.<\/p>\n This method uses nephelometric technology, which measures light scatter at at 90-degree angle from the initial light path 16<\/sup>. The photodetector must be centered at that angle, and cannot extend more than 30 degrees from that center point. To minimize differences in light scatter measurements, the method states that the incident and scattered light cannot travel more than 10 cm from the light source to the photodetector 15<\/sup>. Additional photodetectors are permitted under this method, provided that the 90-degree angle is the primary detector.<\/p>\n EPA Method 180.1 further requires that the light source used in each turbidity meter be a tungsten lamp with a color temperature between 2000 K and 3000 K 15<\/sup>. This means that the tungsten output is polychromatic, or broadband in spectrum. When the light reaches the photodetector, the spectral peak response should be between 400-600 nm. The use of a wide spectral band means that the turbidity meter may be affected by colored samples. As dissolved colored matter can absorb some wavelengths, the accuracy of the meter may decrease 16<\/sup>. However, a broadband spectrum also allows the meter to be sensitive to smaller particles. This sensitivity means a tungsten lamp source will provide a more accurate response than a monochromatic light source when measuring a sample with very fine particles 16<\/sup>.<\/p>\n The use of a tungsten lamp as a light source requires a daily calibration check and frequent recalibration 16<\/sup>. This is due to the incandescent decay inherent in the lamp. As the lamp slowly burns out, much like any other incandescent light bulb, the light output will decrease as well, altering the measurement reading 16<\/sup>. Frequent recalibration minimizes any errors due to light decay.<\/p>\n Instruments in compliance with the EPA Method 180.1 are suitable for measuring turbidity levels between 0-40 NTU (nephelometric turbidity units). These turbidity meters should have a resolution of 0.02 NTU or better in water with a turbidity of less than 1 NTU 15<\/sup>. However, these turbidity meters will not be as accurate at turbidity levels above 40 NTU. At higher levels, the relationship between light scatter and turbidity becomes non-linear. This means that the amount of scattered light that can reach the photodetector decreases, limiting the capabilities of the instrument 16<\/sup>. Instead, these instruments are best used when monitoring treated water, as there is little color interference and limited turbidity.<\/p>\n The EPA Method 180.1 does allow for dilution if the sample is over 40 NTU 6<\/sup>. Once the sample is diluted below 40 NTU and remeasured, the new reading is multiplied by the dilution factor to calculate the turbidity of the original sample 31<\/sup>.<\/p>\n NTU = (A * (B + C)) \/ C <\/strong> <\/a><\/p>\n The International Organization for Standardization developed a stricter design standard known as ISO 7027 Water Quality\u2014Determination of Turbidity 16<\/sup>. This design standard attempts to ensure that turbidity sensors and meters in compliance with this method would have good repeatability and comparability 16<\/sup>. While it is in common use across Europe, this method is not approved by the USEPA for drinking water regulations 18<\/sup>.<\/p>\n Best known for its requirement of a monochromatic light source, ISO 7027 eliminates most color interferences 18<\/sup>. However, there is some ambiguity and misdirection regarding instrument compliance in this area. This method specifically requires a monochromatic light source at a wavelength of 860 nm, with a spectral bandwidth of 60 nm 18<\/sup>. This allows the wavelength to vary +\/- 30 nm from 860, for a light source range of 830-890 nm 32<\/sup>. While both LEDs and filtered tungsten filament lamps can be used as a monochromatic light source, they do not necessarily fall within the specified range. White-light LEDs do not meet the ISO 7027 requirements.<\/p>\n Furthermore, some instrument manuals and turbidity guides refer to the ISO light wavelength requirement as \u201cNear-IR\u201d 18<\/sup>. Near-IR, or near-infrared, encompasses the range of 780-900 nm, beyond the specifications of ISO 7027. While the near-IR range meets the same goals for the restricted light source, (reduced color interference and stray light error), it does not necessarily mean compliance 18<\/sup>. Most instruments in compliance with this method use a 860 nm LED light source 18<\/sup>.<\/p>\n The ISO 7027 method requires a primary photodetector angle of 90 degrees +\/- 2.5 degrees 18<\/sup>. Additional detection angles are allowed (such as attenuation), but the nephelometric 90-degree detector must be the primary measurement source. The acceptance angle of the detector should extend 20-30 degrees (+\/- 10-15 degrees)51<\/sup>. This is a more precise requirement than the EPA Method 180.1, which allows for +\/- 30 degrees from the right angle 32<\/sup>. Like EPA Method 180.1, light path distance is limited to 10 cm (incident light + scattered light) 11<\/sup>.<\/p>\n For turbidities between 0-40 NTU, the recommended units for this method are Formazin Nephelometric Units (FNU) 18<\/sup>. This range can be extended by diluting the sample until it falls below 40 NTU, and then multiplying by the dilution factor. The USGS suggests that this method can be used up to 1000 NTU with a single photodetector, or up to 4000 NTU if multiple detectors are used (ratiometric) 18<\/sup>. If multiple detectors are used, units should be Formazin Nephelometric Ratio Units (FNRU).<\/p>\n Both EPA 180.1 and ISO 7027 use nephelometric technology calibrated by a formazin standard 14<\/sup>. However, the differences in light source and the slight differences in design create different measurement results. ISO 7027 has the advantage that near-infrared light is rarely absorbed by colored particles and molecules, reducing error that would be present with a broadband light source 18<\/sup>. Furthermore, LEDs tend to be more stable over time, requiring less calibration 45<\/sup>. However, as longer wavelengths are less sensitive to small particles, ISO 7027 will produce slightly lower turbidity readings than EPA 180.1 at low turbidities 32<\/sup>. The Great Lakes Instrument Method 2 doubles the number of photodiodes and photodetectors used in the average turbidity instrument 16<\/sup>. It also doubles the number of measurements taken. As such, this design is also known as a modulated four-beam turbidimeter. By using two measurements, two light sources, and two detectors, this method can compare results between the detectors and cancel out errors 18<\/sup>.<\/p>\n This method requires 860 nm LEDs, which allows for color compensation, much as the single beam ISO 7027 method does 18<\/sup>. The LEDs alternate light pulses every half second. The photodetectors take simultaneous readings, providing an \u201cactive signal\u201d and \u201creference signal\u201d 16<\/sup>. The detector directly across from the active LED is considered the active signal, while the detector at a 90-degree angle is considered the reference signal. Every half second, the active and reference signals switch as the second LED pulses 16<\/sup>. Thus the GLI2 method provides two active and two reference measurements to determine each reading. The ratiometric calculations used to determine turbidity mean that the light input and the output are directly proportional. Any errors that may appear are thus mathematically canceled out 16<\/sup>.<\/p>\n A modulated-four beam ratiometric algorithm can use the following formula 37<\/sup>:<\/p>\n NTU = Calslope<\/sub> * Sqrt((Active1 * Active2) \/ (Reference1 * Reference2)) – Cal0<\/sub><\/strong><\/p>\n As fouling, sediment or color interference affect both detectors equally, any potential errors are nullified 37<\/sup>.<\/p>\n Based on the ratiometric (directly proportional) algorithms used to calculate turbidity, the GLI2 method allows for increased sensitivity and error cancellation in the 0-100 NTU range 16<\/sup>. However, this method loses some accuracy as turbidity levels rise above 40 NTU 18<\/sup>. This is due to the the increased light intensity. As turbidity increases, the intensity of the scattered light will also increase 17<\/sup>. GLI2 instruments are ideal for lower turbidity ranges, and when measuring in the 0-1 NTU range in particular, they are extremely accurate 16<\/sup>.<\/p>\n Due to its multi-beam design, the USGS recommends using Formazin Nephelometric Multibeam Units (FNMU) instead of NTU as the turbidity units for this method 18<\/sup>. Instruments with this design are still classified under nephelometric technology as they use photodetectors at 90-degree angles. The Hach Method 10133 is an EPA-approved turbidity measurement method 18<\/sup>. While it is also based on nephelometric technology (90 angle), Hach Method 10133 uses a laser light source as opposed to a tungsten lamp or infrared LED. It is not recommended for use when turbidity levels exceed 5.0 NTU 30<\/sup>.<\/p>\n To be in compliance with this method, the laser diode must emit red light, with a wavelength between 630 nm and 690 nm 30<\/sup>. As with the EPA Method 180.1 and the ISO 7027 method, the total distance that the light beam travels cannot exceed 10 cm. The detector must be set at 90 degrees from the incident light path, and must be connected to a photomultiplier tube (PMT) via a fiber-optic cable 30<\/sup>. Fiber-optic cables may also be used to carry light from the diode to the sample 30<\/sup>. The PMT is used to increase the sensitivity of the photodetector. This setup is also considered an in-line or on-line process stream method as it uses sample lines instead of a sample cell or a dynamic instrument (in-situ turbidity sensor) 18,30<\/sup>.<\/p>\n With a laser diode as a light source, and photomultiplier tube connected to the detector, instruments in compliance with this method can detect extremely low turbidity levels 20<\/sup>. Due to the heightened resolution of this method, units for this method are expressed as milli-Nephelometric Turbidity Units (mNTU) (20). Thus the recommended range for these instruments is 0-5 NTU (0-5000 mNTU). Unlike the previous methods, Hach Method 10133 is not used with turbidity sensors or meters. It is designed for on-line, or process monitoring 30<\/sup>. Instruments in compliance with this method are ideal at very low turbidity levels, such as monitoring drinking water or effluent from wastewater treatment plants 18<\/sup>. Standard Methods 2130B (as it is today) was established by the American Public Health Association (APHA) in Standard Methods for the Examination of Water and Wastewater, 19th edition 32<\/sup>. Nearly identical to USEPA Method 180.1, Standard Methods 2130B clearly defines the basis of nephelometric technology, as well as the methods for creating a proper primary calibration standard 31<\/sup>. While the two methods are often interchanged, most instruments and reporting procedures default to the EPA Method 180.1, as it is more well known and more commonly used 32<\/sup>.<\/p>\n Established two years apart, (1993 and 1995 respectively), both the USEPA Method 180.1 and Standard Methods 2130B maintain the same physical requirements for compliant turbidity meters. Specifically, each method requires a tungsten-filament lamp light source with a color temperature of 2200-3000K 16,31<\/sup>. They also both require the photodetector to be centered at 90 degrees, and not to stretch more than 30 degrees from that point. The light path travelled by both incident and scattered light must be no more than 10 cm combined from the light source to the detector. Finally, the photodetector must have spectral response peak between 400-600 nm 31<\/sup>.<\/p>\n Despite all of the overlap, there are two minor differences worth noting between Standard Methods 2130B and USEPA Method 180.1. The first difference is the definition of primary calibration standard 11<\/sup>. According to Standard Methods, the only acceptable primary standard is formazin, made from scratch by the user, following the specific instructions outlined in this method 11<\/sup>. This includes the specified filter size of 0.1 um if the prepared formazin needs to be diluted (EPA Method 180.1 allows a filter size of 0.45 um) 31<\/sup>. However, method 2130B goes on to state that user-prepared formazin should be a last resort due to the use of carcinogenic compounds in its preparation 31<\/sup>. Instead, Standard Methods strongly recommends using a commercial or manufacturer-supplied calibration solution. These solutions, whether made from a commercial stock suspension of formazin, styrene-divinylbenzene copolymers, latex suspensions or other polymer suspensions are all considered secondary standards 31<\/sup>. The USEPA Method 180.1, on the other hand, considers user-prepared formazin, commercial formazin and AMCO-AEPA-1 styrene-divinylbenzene polymer standards all to be primary standards. Only manufacturer-supplied latex suspensions and metal oxide\/polymer gel suspensions are called secondary standards by this method 31<\/sup>.<\/p>\n The second difference is in the measurement range of these methods. The USEPA Method 180.1 is limited to 0-40 NTU 32<\/sup>. Any samples with turbidities outside of this range must be diluted to below 40 NTU. The resulting measurement is then multiplied by the dilution factor to determine the original turbidity 31<\/sup>.<\/p>\n The 18th edition of Standard Methods (1992) also allowed this dilution method and included it as a step of the measurement procedure for samples with turbidities over 40 NTU 35<\/sup>. However, every edition since (starting with the 19th edition in 1995), has removed this step of the measurement procedure 31,33,34<\/sup>. Instead, the Standard Methods 2130B, as it is known today, goes beyond this range, allowing turbidity levels over 1000 NTU to be measured. The measurement procedures now specify that dilution is to be avoided whenever possible 31,33,34<\/sup>. Standard Methods explains that when a sample is diluted, the composition of the sample may change, rendering the resulting measurement less than accurate. Even so, as EPA Method 180.1 allows dilution, all Standard Methods 2130B (from the 18th edition through the 22nd) are considered USEPA approved 41,47<\/sup>. These four methods were approved as alternate test procedures for measuring turbidity in drinking water in 2009 by the USEPA. The term \u201calternate test procedures\u201d (ATP), is used as these methods use the same technique as an EPA-approved method (nephelometry) without creating an entirely brand new method 42<\/sup>. To be approved, each method needs to produce comparative results relative to EPA Method 180.1 40<\/sup>.<\/p>\n Mitchell Method M5271<\/strong><\/p>\n The Mitchell Method M5271 is similar to Hach Method 10133 as it uses laser nephelometry to determine turbidity in an on-line or process monitoring instrument. The laser light source must emit a wavelength of 650 +\/- 30 nm 40<\/sup>. This is a shift of 10 degrees from the Hach method, which uses a laser diode at 630-690 nm. It is also very similar to EPA Method 180.1, as it limits light travel to 10 cm and allows the photodetector to extend +\/- 30 degrees from the 90-degree center 40<\/sup>. This method does introduce some new technology, as it requires a bubble trap and anti-fog windows 43<\/sup>. To be compliant with this method, the turbidity sensor must be able to withstand up to 30 psig of pressure 43<\/sup>. Mitchell Method M5271 is applicable in the range from 0-40 NTU.<\/p>\n Mitchell Method M5331<\/strong> Orion Method AQ4500<\/strong><\/p>\n The Orion Method AQ4500 was developed by Thermo Scientific and is based on the use of their turbidity meter, Thermo Orion AQUAfast Turbidimeter Model AQ4500. This method follows all of the requirements of EPA Method 180.1 except for the specified light source. This method still requires a 90-degree photodetector with a spectral response between 400 nm and 600 nm, and incident and scattered light cannot travel further than 10 cm combined 40<\/sup>.<\/p>\n Instead of using a polychromatic tungsten lamp as a light source, the Orion method AQ4500 uses a \u201cwhite\u201d LED. To achieve a broadband output with a typically narrow band LED, this method uses a phosphorus coated blue LED 45<\/sup>. This expands the spectral output from the blue 450 nm wavelength to a wide spectrum response similar to a tungsten source\/cadmium sulfide detector combination 45<\/sup>.<\/p>\n Furthermore, the use of an LED light source allows for rapid pulsing operation. By pulsing the light, this method permits synchronous detection 40<\/sup>. Synchronous detection means that any stray light or electronic-induced errors can be reduced and nearly cancelled out. The Orion Method AQ4500 also reduces errors due to color absorption by using two photo detectors. In addition to the nephelometric, 90-degree detector, the AQ4500 turbidimeter has a transmitted (180-degree) light detector 46<\/sup>. The light that reaches the transmitted detector is used as a reference beam against the nephelometric scattered light beam. This allows for color compensation due to absorption 45<\/sup>.<\/p>\n To remain compliant with the EPA, the Orion Method AQ4500 has a limited range of 0.06-40 NTU ![\"Backscatter](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_sediment-streamflow.jpg\")
\n<\/a><\/p>\nA Note on Turbidity, Turbidity Units and Unit Conversions<\/h2>\n
![\"Sediment](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/Sediment_load_elhwa_river_glines_canyon_dam_removal_johnfelis_usgs1-300x230.jpg\")
![\"These](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_ntu-fnu.jpg\")
![\"A](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/TurbiditySensorBodySamplesRainfall.jpg\")
![\"turbidity_equation_tss\"](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_equation_tss.jpg\")
\nNTU = a * TSSb<\/sup><\/strong>
\nNTU = Turbidity Measurement
\nTSS = Suspended solids measurement in mg\/L
\na = regression-estimated coefficient
\nb = regression-estimated coefficient, approximately equal to 1<\/p>\n![\"turbidity_equation_ssc\"](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_equation_ssc.jpg\")
\nLog10<\/sub>(SSC) = a *Log10<\/sub>(Turb) + b<\/strong>
\nSSC= suspended-sediment concentration, in mg\/L
\nTurb= turbidity, in formazin nephelometric units (FNU)
\na= regression coefficient
\nb= Duan\u2019s bias correction factor<\/p>\n![\"If](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_tss-discharge.jpg\")
Quality Standards<\/h2>\n
![\"The](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_units.jpg\")
\n<\/a><\/p>\nEPA Method 180.1<\/h3>\n
![\"Nephelometry](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_scattered90.jpg\")
![\"The](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_tungsten.jpg\")
![\"Procedure](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_equation_ntu.jpg\")
\nA = NTU found in diluted sample,
\nB = volume of dilution water, mL, and
\nC = sample volume taken for dilution, mL.<\/p>\nISO 7027<\/h3>\n
![\"ISO](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_nephelometer_red.jpg\")
![\"As](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_measure-e1410181664886-300x165.jpg\")
\n<\/a><\/p>\nGLI Method 2<\/h3>\n
![\"A](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_modulatedfourbeam.jpg\")
![\"turbidity_equation_cal\"](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_equation_cal.jpg\")
\nCalslope<\/sub> = Calibration coefficient
\nActive1 = 90 Degree Detector Current (Light Source 1 ON, Light Source 2 OFF)
\nActive2 = 90 Degree Detector Current (Light Source 1 OFF, Light Source 2 ON)
\nReference1 = Transmitted Detector Current (Light Source 1 ON, Light Source 2 OFF)
\nReference2 = Transmitted Detector Current (Light Source 1 OFF, Light Source 2 ON)
\nCal0<\/sub> = Calibration coefficient<\/p>\n
\n<\/a><\/p>\nHach Method 10133<\/h3>\n
![\"Hach](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_hach-method.jpg\")
\n<\/a><\/p>\nStandard Methods 2130B<\/h3>\n
![\"Nephelometric](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_nephelometer.jpg\")
<\/p>\n![\"Approved](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_standards.jpg\")
\n<\/a><\/p>\nMitchell Methods M5271, M5331; Orion AQ4500; AMI Turbiwell<\/h3>\n
![\"Figure](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/Figure22_Mitchell_Patent-721x1024.png\")
\nThe second Mitchell method – Mitchell Method M5331, does not use a laser. Instead, it requires an LED as a light source 40<\/sup>. The LED must emit a wavelength of 525 +\/- 15 nm 44<\/sup>. All other requirements match Mitchell Method 5271 in terms of distance traveled by incident and scattered light, location and spread of the photodetector, and the use of a Mitchell\/Mersch bubble trap and anti-fog windows 44<\/sup>. It also is applicable for turbidities between 0-40 NTU. Both Mitchell Method M5331 and M5271 are designed for process monitoring, or on-line continuous turbidity monitoring. On-line instruments usually divert a sample flow, with the sensing instrumentation submerged below the water 16<\/sup>. This design is appropriate for continuously monitoring drinking water or wastewater effluent.<\/p>\n![\"The](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_detector-led.jpg\")
![\"The](\"https:\/\/www.fondriest.com\/environmental-measurements\/wp-content\/uploads\/2014\/09\/turbidity_color-compensation.jpg\")