2.1. Revision of current meridian arc length formulae

In this section, an overview of the most important geodetic formulae is given. The methods and formulae used to calculate the meridian arc length for sailing calculations on the ellipsoid are included in navigational software and are important to the accuracy embedded within them. The formulae for the meridian arc length on an ellipsoid presumed Earth originate from integrating the curvature of the meridian, which is the curvature of an ellipse. The integration of the curvature from the equator to a reduced latitude (β) is expressed in Equation (1).

(1)$$M(\beta ) = \int\limits_0^\beta {(a^2 \sin ^2 \beta + b^2 \cos ^2 \beta )^{1/2} d\beta} $$

where, a=Major radius; b=Semi-Minor radius.

This integral (Equation (1)) is a famous integral called the “complete elliptic integral of the second type”, an integral which cannot be expressed in closed forms with terms of familiar calculus, except when e, the eccentricity of the spheroid equals zero, then it transforms the ellipse into a circle. As geodetic latitude (φ) is the most common latitude used in navigational systems and for practical use, there is a need to transfer the relationship between geodetic latitude (φ) and reduced latitude (β). Taking the relationship between geodetic latitude and reduced latitude (Equation (2), Figure 1) gives the meridian arc length integral with respect to geodetic latitude (φ) (Equation (3).

(2)$$\beta = \tan ^{ - 1} ((1 - e^2 )^{1/2} \tan \varphi )$$

(3)$$M_0^\varphi = \int_0^\varphi {\displaystyle{{a(1 - e^2 )} \over {(1 - e^2 \;\sin ^2 \varphi )^{3/2}}} d\varphi} $$

Figure 1. Meridian plane with reduced (β) and geodetic (ϕ) latitude of point P on the spheroid.

As Equation (3) originates from an elliptic integral of the second type, it also cannot be evaluated in a “closed” form. The calculation can be performed by the binomial expansion of the denominator with integration by parts. In the binomial expansion of Equation (3), since the powers of the denominator are not a positive integer (here it is −3/2), the expansion would be infinite, and when expressed in a general formula form yields Equation (4).

(4)$$S(\varphi ) = a(1 - e^2 )\int_0^\varphi {\left[ {\sum\limits_{k = 0}^\infty {( - 1)^k \left( {\matrix{ { - \displaystyle{3 \over 2}} \cr k \cr}} \right)} (e^2 \sin ^2 \varphi )^k} \right]d\varphi} $$

Since the powers of e are very small, Equation (4) is a rapidly converging series, so the number of terms retained depends on the accuracy required. By rearranging Equation (4) with general terms of even powers of sine and further integrating by parts gives the following general formula of the meridian arc length in Equation (5):

(5)$$S(\varphi ) = a(1 - e^2 )\left[ {M_0 \varphi + \sum\limits_{i = 1}^\infty {M_{2i} \sin (2 \cdot i \cdot \varphi} )} \right]$$

where

$$M_0 = \sum\limits_{k = 0}^\infty {\displaystyle{{( - 1)^k} \over {2^{2k}}} \left( {\matrix{ { - \displaystyle{3 \over 2}} \cr k \cr}} \right)\left( {\matrix{ {2k} \cr k \cr}} \right)e^{2k}} \quad {\rm and}\quad M_{2i} = \sum\limits_{k = i}^\infty {\displaystyle{{( - 1)^{i + k}} \over {2^{2k} i}}\left( {\matrix{ { - \displaystyle{3 \over 2}} \cr k \cr}} \right)\left( {\matrix{ {2k} \cr {k - i} \cr}} \right)e^{2k}}. $$

The binomial series for half integer multiples is defined by:

$$\left( {\matrix{ {{\rm -} \displaystyle{3 \over 2}} \cr k \cr}} \right) = \displaystyle{{\left( {\displaystyle{{{\rm -} 3} \over 2}} \right) \cdot \left( {\displaystyle{{{\rm -} 5} \over 2}} \right) \cdots \left( {\displaystyle{{{\rm -} 3} \over 2}{\rm -} k + 1} \right)} \over {k \cdot (k{\rm -} 1) \cdots 1}},$$

where k is the truncated term.

After expanding and collecting the coefficients of Equation (5) truncated at order e ²⁰ and M ₂₀ with computer programs that do symbolic calculating, the coefficients are shown below in Equation (6). This confirms the results of Equation (5) to be accurate, as the coefficients up to M ₈ first given by Delambre (Reference Delambre1799) are the same.

(6)$${\eqalign{\left[ {.5 \matrix{ {M_0} \cr {M_2} \cr {M_4} \cr {M_6} \cr {M_8} \cr {M_{10}} \cr {M_{12}} \cr {M_{14}} \cr {M_{16}} \cr {M_{18}} \cr {M_{20}} \cr}} \right] = & \left[ {\matrix{ 1 & {{\displaystyle{3 \over 4}}} & {{\displaystyle{{45} \over {64}}}} & {{\displaystyle{{175} \over {256}}}} & {{\displaystyle{{11025} \over {16384}}}} & {{\displaystyle{{43659} \over {65536}}}} & {{\displaystyle{{693693} \over {1048576}}}} & {{\displaystyle{{2760615} \over {1073741824}}}} \cr 0 & { - {\displaystyle{3 \over 8}}} & { - {\displaystyle{{15} \over {32}}}} & { - {\displaystyle{{525} \over {1024}}}} & { - {\displaystyle{{2205} \over {4096}}}} & { - {\displaystyle{{72765} \over {131072}}}} & { - {\displaystyle{{297297} \over {524288}}}} & { - {\displaystyle{{19324305} \over {33554432}}}} \cr 0 & 0 & {{\displaystyle{{15} \over {256}}}} & {{\displaystyle{{105} \over {1024}}}} & {{\displaystyle{{2205} \over {16384}}}} & {{\displaystyle{{10395} \over {65536}}}} & {{\displaystyle{{1486485} \over {8388608}}}} & {{\displaystyle{{6441435} \over {33554432}}}} \cr 0 & 0 & 0 & { - {\displaystyle{{35} \over {3072}}}} & { - {\displaystyle{{105} \over {4096}}}} & { - {\displaystyle{{10395} \over {262144}}}} & { - {\displaystyle{{55055} \over {1048576}}}} & { - {\displaystyle{{2147145} \over {335544332}}}} \cr 0 & 0 & 0 & 0 & {{\displaystyle{{315} \over {131072}}}} & {{\displaystyle{{3465} \over {524288}}}} & {{\displaystyle{{99099} \over {8388608}}}} & {{\displaystyle{{585585} \over {33554432}}}} \cr 0 & 0 & 0 & 0 & 0 & { - {\displaystyle{{693} \over {1310720}}}} & { - {\displaystyle{{9009} \over {5242880}}}} & { - {\displaystyle{{117117} \over {33554432}}}} \cr 0 & 0 & 0 & 0 & 0 & 0 & {{\displaystyle{{1001} \over {8388608}}}} & {{\displaystyle{{15015} \over {33554432}}}} \cr 0 & 0 & 0 & 0 & 0 & 0 & 0 & { - {\displaystyle{{6435} \over {234881024}}}} \cr 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \cr 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \cr 0 & 0 & 0 & 0 & 0 & 0 & 0 & 0 \cr}} \right. \cr \cr & \left. {.5\matrix{ {{\displaystyle{{703956825} \over {1073741824}}}} & {{\displaystyle{{2807136475} \over {4294967296}}}} & {{\displaystyle{{44801898141} \over {68719476736}}}} \cr { - {\displaystyle{{78217425} \over {134217728}}}} & { - {\displaystyle{{5052845655} \over {8589934592}}}} & { - {\displaystyle{{20364499155} \over {34359738368}}}} \cr {{\displaystyle{{109504395} \over {536870912}}}} & {{\displaystyle{{459349605} \over {2147483648}}}} & {{\displaystyle{{61093497465} \over {274877906944}}}} \cr { - {\displaystyle{{9954945} \over {134217728}}}} & { - {\displaystyle{{357271915} \over {4294967296}}}} & { - {\displaystyle{{1566499935} \over {17179869184}}}} \cr {{\displaystyle{{49774725} \over {2147483648}}}} & {{\displaystyle{{247342095} \over {8589934592}}}} & {{\displaystyle{{4699499805} \over {137438953472}}}} \cr { - {\displaystyle{{765765} \over {134217728}}}} & { - {\displaystyle{{35334585} \over {4294967296}}}} & { - {\displaystyle{{939899961} \over {85899345920}}}} \cr {{\displaystyle{{546975} \over {536870912}}}} & {{\displaystyle{{3926065} \over {2147483648}}}} & {{\displaystyle{{1566499935} \over {549755813888}}}} \cr { - {\displaystyle{{109395} \over {939524096}}}} & { - {\displaystyle{{35334585} \over {120259084288}}}} & { - {\displaystyle{{39491595} \over {68719476736}}}} \cr {{\displaystyle{{109395} \over {17179869184}}}} & {{\displaystyle{{2078505} \over {68719476736}}}} & {{\displaystyle{{92147055} \over {1099511627776}}}} \cr 0 & { - {\displaystyle{{230945} \over {154618822656}}}} & { - {\displaystyle{{1616615} \over {206158430208}}}} \cr 0 & 0 & {{\displaystyle{{969969} \over {2748779069440}}}} \cr}} \right]\left[ {.5\matrix{ 1 \cr {e^2} \cr {e^4} \cr {e^6} \cr {e^8} \cr {e^{10}} \cr {e^{12}} \cr {e^{14}} \cr {e^{16}} \cr {e^{18}} \cr {e^{20}} \cr}} \right]} $

Further extension of the equation can give the direct calculation of the meridian arc length between two geodetic latitudes φA and φB; this is shown in Equation (7).

(7)$$S(\varphi )_{\varphi _B} ^{\varphi _A} = a(1 - e^2 )\left[ {M_0 (\varphi _B - \varphi _A ) + \sum\limits_{i = 1}^\infty {M_{2i} (\sin (2 \cdot i \cdot \varphi _B} ) - \sin (2 \cdot i \cdot \varphi _A ))} \right]$$

Very accurate results are obtained by Equation (5) with M ₄ or M ₆ terms of up to eight or ten powers of e (e ⁸, e ¹⁰). For sailing calculations on the ellipsoid, using M ₂ terms up to eight or ten powers of e will be sufficient, whereas in other areas of application it will be determined on the degree of accuracy needed. The formulae above are presented in textbooks such as the Admiralty Manual of Navigation (1987), and Bowditch's American Practical Navigator (Reference Bowditch1977) in non-general forms. Equation (5) can be further manipulated and transformed into other forms, such as Bessel's formula and Helmert's formula which require the introduction of new terms of n $\left( {n = (1{\rm -} \sqrt {1 + e^2} )/1 + \sqrt {1 + e^2}} \right)$. (Kawase, Reference Kawase2011; Deakin and Hunter, Reference Deakin and Hunter2009; Krüger, Reference Krüger1912).

2.2. The Proposed Formulae by Pallikaris, Tsoulos and Paradissis

Since the WGS-84 datum is used for electronic chart systems. Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) proposed new formulae to calculate the meridian arc, by calculating Equation (5) with M ₀ and M ₂ terms of up to the eighth powers of e then neglecting M ₄ and above terms in WGS-84 standards. They give the following formula used to calculate the meridian arc:

(8)$$M_{\varphi _A} ^{\varphi _B} = 111132.952546922 \cdot \Delta \varphi - 16038.508615363\left( {\sin \left( {\displaystyle{{\varphi _B \cdot \pi} \over {90}}} \right) - \sin \left( {\displaystyle{{\varphi _A \cdot \pi} \over {90}}} \right)} \right)$$

These coefficients are obtained by simply truncating the M ₀, M₂ values up to the eighth powers of e with the ellipsoid major radius in metres. Taking into account that computer programs use radian units in trigonometry calculations, the transformation of degree units into radians must be allowed for (1° equals π/180 radian units).

The main concept of Pallikaris, Tsoulos and Paradissis's methods is to calculate and only use the desired coefficient terms (M ₀, M₂ and so on) up to certain powers of e. This neglects the above coefficient terms which are not desired and truncates each term to a certain value of e to the desired accuracy. The reason they do this is that in the meridian arc general formula Equation (5), the powers of e are very small causing the values of each coefficient term to approximate a certain value if the truncated powers of e terms are enough, and in the binominal theorem which the meridian arc formula uses for its coefficient terms, the denominator will greatly surpass its numerator upon reaching certain high coefficient terms, causing the influences of higher terms in the meridian arc formula to greatly decrease after a certain first few terms.

By further expanding their method to M ₀, M₂ and M ₄ terms of up to the eighth powers of e, we can obtain new 3 coefficient formulas as below:

(9)$$\hskip-10pt\eqalign{ M_{\varphi _A} ^{\varphi _B} =& 111132.952546922 \cdot \Delta \varphi - 16038.508615363\left( {\sin \left( {\displaystyle{{2 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{2 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)\hskip-22pt \cr & + 16.832599651\left( {\sin \left( {\displaystyle{{4 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{4 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)} $$

Correspondingly, expanding their method up to M ₆ terms of up to the eighth powers of e are shown below:

(10)$$\hskip-35pt\eqalign{ M_{\varphi _A} ^{\varphi _B} =& 111132.952546922 \cdot \Delta \varphi \!-\! 16038.508615363\left( {\sin \left( {\displaystyle{{2 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{2 \cdot \varphi _A \cdot \pi} \over {180}}} \right)}\! \right)\hskip-35pt \cr & + 16.832599651\left( {\sin \left( {\displaystyle{{4 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{4 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)\cr & - 0.021980996\left( {\sin \left( {\displaystyle{{6 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{6 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)} $$

And whereas up to M ₈ terms and eighth powers of e is the equation below:

(11)$$\hskip-35pt\eqalign{ M_{\varphi _A} ^{\varphi _B} =& 111132.952546922 \cdot \Delta \varphi \!-\! 16038.508615363\left( {\sin \left( {\displaystyle{{2 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{2 \cdot \varphi _A \cdot \pi} \over {180}}} \right)}\! \right)\hskip-35pt \cr & + 16.832599651\left( {\sin \left( {\displaystyle{{4 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{4 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)\cr & - 0.021980996\left( {\sin \left( {\displaystyle{{6 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{6 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right) \cr & + 0.000030579\left( {\sin \left( {\displaystyle{{8 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{8 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)} $$

In the method presented (Pallikaris et al., Reference Pallikaris, Tsoulos and Paradissis2009), terms up to the eighth power of e are used. For accuracy comparisons, we further extend this method and present Pallikaris, Tsoulos and Paradissis's formula with up to 20 powers of e with M ₀ and M ₂ terms to see how they affect the accuracy of the equation, the new two coefficient meridian arc formula is presented as below:

(12)$$\eqalign{M_{\varphi _A} ^{\varphi _B} = 111132.9525479019 \cdot \Delta \varphi\! - 16038.5086629759\left( {\sin \left( {\displaystyle{{2 \cdot \varphi _B \cdot \pi} \over {180}}} \right)\! - \sin \left( {\displaystyle{{2 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \!\right)$$

And in addition, the 3 coefficient Pallikaris, Tsoulos and Paradissis's meridian arc formula up to 20 powers of e with M ₀, M₂ and M ₄ terms is:

(13)$$\hskip-15pt\eqalign{M_{\varphi _A} ^{\varphi _B} =& 111132.9525479019 \cdot \Delta \varphi - 16038.5086629759\left( {\sin \left( {\displaystyle{{2 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{2 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)\hskip-35pt \cr & + 16.832613263\left( {\sin \left( {\displaystyle{{4 \cdot \varphi _B \cdot \pi} \over {180}}} \right) - \sin \left( {\displaystyle{{4 \cdot \varphi _A \cdot \pi} \over {180}}} \right)} \right)} $$

These formulae are compared in Section 5 of this paper, and in addition we present the errors and influences they have on the meridian arc formula. Where in the above meridian arc length equations, the distances are calculated in metres, conversion to nautical units is achieved by dividing the equation by 1852, as 1 nautical mile equals 1852 metres.

5.1. Comparison

Comparison of the different formulae for calculating the meridian arc distance are evaluated and shown below, the compared formulae are

1. 1. The original formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) (Equation (8)).

2. 2. The extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with up to eighth powers of e and M ₄ terms (Equation (9)).

3. 3. The extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with up to eighth powers of e and M ₆ terms (Equation (10)).

4. 4. The extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with up to eighth powers of e and M ₈ terms (Equation (11)).

5. 5. The extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with up to 20th powers of e and M ₂ terms (Equation (12)).

6. 6. The extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with up to eighth powers of e and M ₄ terms (Equation (13)).

7. 7. The propsosed new formulae in this paper with n=0∼5 (Equation (15), n=0∼5, m=91).

A comparison must always have a standard to be compared with to determine whether the outcomes are good or bad. The comparison standard used here is Equation (5) with up to M ₂₀ terms and 20 powers of e, as this formula provides micrometre accuracies for the meridian arc length on an ellipsoid presumed Earth. The distances calculated in this formula are compared with Vincenty's formula (Vincenty, Reference Vincenty1975), which give accuracies within 0·5 mm on the ellipsoid, and are shown in Table 2. With Vincenty's formula being considered as one of the most precise methods with millimetre accuracies on the WGS-84 ellipsoid, the results in Table 2 show that Equation (5) with up to M ₂₀ terms and 20 powers of e should be sufficient as the comparison standard used here.

Table 2. Comparison of Equation (5) with M ₂₀ terms up to 20 powers of e with Vincenty's formula (1975).

*above distances are calculated in metres.

The errors between the compared formulae with Equation (5) having M ₂₀ terms and up to 20 powers of e are shown in Table 3 expressed with the units of metres. These comparisons are based on the calculations of 91 meridian arcs lengths contained from the equator to parallel latitudes starting from 0° to 90° latitude with 1° increments.

Table 3 is expressed in units of metres. These comparisons are based on the calculations of 91 meridian arcs lengths contained from the equator to parallel latitudes starting from 0° to 90° latitude with 1° increments. For a simple and clear view on how the discrepancies compare to each another, they are also presented in Figures 3 and 4, where Figure 3 shows the error differences of Equations (8) and (15), (where n=0 and m=91) and Figure 4 shows the differences between Equations (8), (9), (10), (11), (12), (13) and (15) (where n=1∼5 and m=91), vertical axis of these figures represent the errors when compared to Equation (5) with M ₂₀ terms and 20 powers of e, where the horizontal axis is the corresponding latitude of the compared meridian arc length distances.

Figure 3 (left). Error comparisons of Equations 8, 15 (n=0, m=91).

Table 3. The errors between the compared formulae and the standard arc length.

* For brevity, only intervals of 5° are shown, m=91 for Equation 13, units are in metres.

This paper also presents the maximum deviation, minimum deviation and standard deviation of each new formula as shown in Table 4. It must be noted as we want the error difference from the standard, this means when calculating the average, maximum and minimum errors an absolute value is used instead of simply using such positive and negative errors provided in Table 3, as this will give a non-meaningful average, maximum and minimum errors. Note that the minimum deviations do not include the initial values for latitude 0°. If included, all minimum deviations shall be zero because at 0° latitude, the meridian arc length of all equations equal zero.

Table 4. Error averages, maximums and minimums and standard deviation.

* above units are calculated in metres.

As data fitting in overdetermined systems is essential for the accuracy of the approximated solution, we compare whether more data inputs (m>91) influence the accuracy of the formulae. Here, we compare the accuracy of the new two coefficients formula (Equation (15), n=1), as this formula with its high accuracy and compactness in calculations would be used most in practical needs. We compare the accuracy of the method when m=91 with 1° increments to 90°, and when m=181 with 0·5° increments to 90°. The results are shown in Table 5, again, the minimum deviations do not include the initial values for 0° latitude.

Table 5. Comparisons between differing m.

*above units are calculated in metres.

5.2. Discussion of comparison results

As shown in Tables 3 and 4, the new formula Equation (15) with one coefficient (n=0) is not accurate enough for precise sailing calculations.

The new formula (Equation (15)) with two coefficients (n=1) is sufficient for practical sailing calculations with an average error of 8 m with a range of 20∼0·2 m errors. It is to be noted that when compared to the formulas presented by Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) (Equation (8), 2009) and extended formula Equation (12) with near identical values, although they all have the same coefficient terms (M ₀ and M ₂) and have almost the same accuracy, our maximum error is larger (20 m vs 17 m), this is because the least squares method includes the non-truncated terms causing the values to not be a sine curve as shown in Equation (8). This causes a continuing rise for latitudes of about 70° and higher. But as one can see from Figure 4, Equation (15) with two terms of coefficients (n=1) maintains a lower maximum error between 0∼70° degrees, and as most shipping routes are between 70° latitude north and south, the new formula (Equation (15) with two terms of coefficients can be considered an acceptable alternative for Equation (8).

Figure 4 (right). Error comparisons of Equations 8, 9, 10, 11, 12, 13 and 15 (n=1∼5, m=91). *Errors in metres.

In Equations (9), (10), and (11), the extended formulae of Pallikaris, Tsoulos and Paradissis's method which are calculated up to eight powers of e and up to M ₄, M₆ and M ₈ terms respectively have no significant difference between each other and also can be considered appropriate for navigational sailing with maximum errors up to 30 metres. Yet, it is to be noted that these all have more than two coefficient terms, and only at below approximately 35° latitude do these equations have a better accuracy than those of the above two coefficient term formula.

The new formula (Equation (15)) with three coefficients (n=2) drastically lowers the errors to millimetre range, which should be sufficient when needing very high accuracy calculations. When compared to the extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with three coefficient terms (Equations (9) and (13)), only Equation (13) of up to 20 powers of e will give repeatable millimetre level accuracy. It is to be noted that although our new least square formula with three coefficient terms (Equation (15), n=2) and the extended formulae of Pallikaris et al. (Reference Pallikaris, Tsoulos and Paradissis2009) with three coefficient terms up to 20 powers of e powers (Equation (13)) have near identical values and both are viable for high accuracy calculations, the least square method is a slightly more accurate (approximately about 3∼4 mm). This is because our method takes account of the non-truncated higher term values and as such demonstrates the use of the least square method implied here.

The new formula (Equation (15)) with four and above coefficients (n=3 and above) shows no significant difference between Equation (5) with M ₁₀ terms up to 20 powers of e, and Vicenty's formula (Vicenty, Reference Vincenty1975), making this new formula with four coefficients a suitable alternative to save computer resources when requiring such high accuracies.

In the extended formulae of Pallikaris, Tsoulos and Paradissis's method, it is to be noted that when calculating up to eight powers of e, taking in more terms of M ₄ to M ₈ does not improve its accuracy drastically. And when taking more powers of e (here, 20 powers of e), their formula with two terms of coefficient does not differ much to those of eight powers of e, it is only when taking three terms and above with more powers of e that the formula becomes drastically more accurate for high accuracy calculations.

There is no significant difference between m=91 and m=181, yet of course m=181 should be more accurate, as more information is given, then the data fitting should be more accurate and a better curve line equation is fitted. It can also be seen that the standard deviation of m=181 is more compact than m=91, meaning the errors do not diverge as far as the origin of zero when compared to m=91.