3. Polarisation

For each pulsar, we produce a high S/N profile by summing the brightest individual observationsFootnote i partially averaged in frequency to 232 channels ( $\approx$ 3.34 MHz channel widths), and full time integration after summing. We show the polarisation profiles in Figures A.1–A.21, integrated to the centre frequency (after correcting for Faraday rotation as described below). All calculations of linear polarisation, L, have been de-biased with a procedure modified from Everett & Weisberg (Reference Everett and Weisberg2001), where, for every bin i across the profile,

(1) \begin{equation} L_{\textrm{true},i} = \begin{cases} \sqrt{L_{\textrm{meas},i}^2 - \sigma_I^2} & \quad \textrm{if}\ |L_{\textrm{meas},i}| \geq |\sigma_{I}| \\[5pt] -\sqrt{|L_{\textrm{meas},i}^2 - \sigma_I^2|} & \quad \textrm{otherwise}, \end{cases}\end{equation}

where $L_\textrm{meas}$ is the measured linear polarisation ( $L^2 = Q^2 + U^2$ ) and $\sigma_I$ is the root-mean-square of the total intensity profile in the off-pulse region.Footnote j We determine the uncertainties on the polarisation position angle (PA, $\psi$ ) following Everett & Weisberg (Reference Everett and Weisberg2001): for each bin i across the profile, if $P_0=L_{\textrm{true},i}/\sigma_{I} > 10$ , the uncertainty is $\sigma_{\psi,i} = \sigma_I/2L_i$ ; otherwise, we determine the uncertainty numerically from the probability distribution (Naghizadeh-Khouei & Clarke Reference Naghizadeh-Khouei and Clarke1993)

(2) \begin{equation} G(\psi, P_0) = \frac{1}{\sqrt{\pi}}\left(\frac{1}{\sqrt{\pi}}+\eta \,e^{\eta^2}[1+\textrm{erf}(\eta)]\right)\,e^{-P_0^2/2},\end{equation}

where $\eta=\frac{P_0}{\sqrt{2}}\cos2(\psi-\psi_\textrm{true})$ and ${\rm erf(\eta)}$ is the Gaussian error function. The uncertainty, $\sigma_\psi$ , can therefore be determined by setting $\psi_\textrm{true}=0$ and adjusting the bounds of integration of the probability distribution to satisfy

(3) \begin{equation} \int_{-1\sigma_\psi}^{1\sigma_\psi} G(\psi,P_0)\,d\psi=68.26\%.\end{equation}

When analysing our pulse profiles with psrchive, it is necessary to consider the noise baseline in each polarisation channel, especially with complicated profiles with emission across the entire phase range. Accurate calibration will set the noise values appropriately, but, when calculating $S/N$ or polarisation fractions, psrchive will ‘subtract the baseline’ by default. For all but one pulsar in our sample, we use the ‘minimum’ baseline estimator,Footnote k which finds a continuous region with the minimum mean by smoothing the profile with a boxcar with custom widths varying from 1% to 90% (where the region width was determined manually for each pulsar). One pulsar for which the ‘minimum’ baseline estimator was not optimal is PSR $\mathrm{J}1421-4409$ (Spiewak et al. Reference Spiewak2020), which instead used the ‘normal’ estimator.Footnote l Note that this pulsar still shows apparent over-polarisation at pulse phases ${\sim}$ 0.6–1.0 (shown in the central panels of Figure A.7), as there is significant emission in both Q and U throughout that range. This pulsar may be similar to PSR J0218+4232 with underlying unpulsed emission (Navarro et al. Reference Navarro, de Bruyn, Frail, Kulkarni and Lyne1995), which would contradict the general assumption that all polarisation channels are consistent with noise over some phase range (the off-pulse baseline). Further study of this pulsar with MeerKAT could reveal the nature of this emission.

We measure significant fractional linear polarisation ( $L/I$ ; from fully time- and frequency-integrated profiles centred at 1 284 MHz, as shown in Figures A.1–A.21) for 180 pulsars in our sample ( ${>}$ 1- $\sigma$ significance), and significant absolute fractional circular polarisation ( $|V|/I$ ) for 119. Our full results are listed in Table 1.

We calculate the RM for each pulsar from the individual observations (fully integrated in time, with 29 frequency channels across the 775.75 MHz band) or, for faint pulsars, from the summed observations (also fully time-integrated, with 29 frequency channels) and list all in Table 1. We use rmfit to determine RMs using a brute force linear polarisation maximisation which is then refined using an iterative fit to the measured PA as a function of frequency. After calculating RM from the individual observations, we then correct for the contributions of the ionosphere using the ionFR software (Sotomayor-Beltran et al. Reference Sotomayor-Beltran2013) with IGSG maps.Footnote m For each pulsar with ${\geq} 10$ corrected RMs, we remove outliers using a basic drop-out algorithm comparing the standard deviation and median-absolute-deviation from the median. Outliers are removed manually for pulsars with fewer observations. We then report the mean of the corrected RM values with the standard deviation as the 1- $\sigma$ uncertainty. For faint pulsars, because we measure the RM from a summed profile, we report the RMs and uncertainties as given by rmfit after correcting by the mean of the ionospheric contributions per pulsar (the uncertainties on the ionospheric corrections are summed in quadrature with the uncertainties given by rmfit). No RMs are given for pulsars with linear polarisation fractions less than $\approx0.05$ ( ${\sim}$ 1.5- $\sigma$ ).

Figure 2. The positions of the MSPs in this sample on an Aitoff projection, with coloured circles indicating sources with measured RMs (including those formally consistent with zero) and black ‘x’ markers indicating sources without measured RMs, as described in the text.

In total, we measure 171 non-zero RMs (at the 1- $\sigma$ level; 163 with 3- $\sigma$ measurements), increasing the number of MSPs with known RMs by 88. To verify the reliability of our measurements, we compare the RMs in the ATNF pulsar catalogue (v1.64) for the 83 MSPs with previously published values and calculate the significance of the difference of the values: $d = \left(\textrm{RM}_\textrm{psrcat} - \textrm{RM}_\textrm{census}\right)/\sqrt{\sigma_\textrm{psrcat}^2 + \sigma_\textrm{census}^2}$ . Nearly 50% of the pulsars have RMs that are 1- $\sigma$ consistent with the previously published values, and 85% of the pairs are consistent to 2.6- $\sigma$ . Given that pulsar RMs are known to vary with time due to inaccurate models of the ionospheric Faraday rotation (e.g., Yan et al. Reference Yan2011), that not all values reported in the ATNF pulsar catalogue are corrected for the ionosphere, and that measurements at different frequencies can result in statistically inconsistent RMs (see, e.g., the position angle fits in Dai et al. Reference Dai2015), differences between our RMs and published values at this level are not unexpected. However, two pulsars have significantly different values in our census and the literature: PSR $\mathrm{J}1502-6752$ has a published value of $-225(2)\,\mathrm{rad\,m}^{-2}$ from Keith et al. (Reference Keith2012), while our measurement is $232.8(2)\,\mathrm{rad\,m}^{-2}$ ; and PSR J0154+1833 has a published value of $21.6(1)\,\mathrm{rad\,m}^{-2}$ (Martinez et al. Reference Martinez2019), while our measurement is $-21.9(6)\,\mathrm{rad\,m}^{-2}$ . Given the consistency of our other RM measurements, we are inclined to believe the Keith et al. (Reference Keith2012) and Martinez et al. (Reference Martinez2019) values suffer from a sign convention error.

We show in Figure 2 the positions of the MSPs in our sample, coloured by their measured RM (black marks indicate the positions of pulsars without measured RMs). Overall, the RMs for our sample do not indicate strong (average) magnetic fields along the lines of sight, with 90% of values in the range $-2.8$ – $2.3\,\unicode{x03BC}\mathrm{G}$ (full range $-6.7$ – $5.0\,\unicode{x03BC}\mathrm{G}$ ).

4. Flux densities and spectral indices

Ideally, pulsar flux densities are obtained using an injected and pulsed broadband calibration signal that can be measured against a source of known flux density to derive a flux scale. While attempting to derive a polarisation calibration solution using the MeerKAT L-Band receiver pulsed cal, we found that the degree of polarisation of the cal often exceeds 105%. This is probably due to the strength of the cal being comparable to the system equivalent flux density and driving the system into a non-linear regime. This made this conventional method unsuitable for absolute flux calibration.

An alternative calibration method involves using the radiometer equation and assuming that the rms of the pulsar baseline region is well-defined by the system equivalent flux density plus the galactic sky temperature divided by the antenna gain. In the presence of unrecognised sources of noise due to RFI, this method can underestimate radio fluxes and must be approached with caution. Nevertheless, as shown in Bailes et al. (Reference Bailes2020), there are many parts of the MeerKAT L-band (856–1 712 MHz) that are almost always devoid of interference, and we found that many of our high DM ( $\mathrm{DM}\,\gtrsim100\,\mathrm{pc\,cm}^{-3}$ ) sources gave very reliable S/N and hence flux values from epoch to epoch across much of the band. To assess the reliability of this method, we computed the modulation indices of the derived flux densities for the five pulsars with the largest DMs in our sample and found them to be between 7–15%, which means that the reliability of the flux densities from epoch to epoch is probably no worse than this figure.

Absolute flux densities for each observation were thus calculated using the radiometer equation and assuming the Haslam et al. (Reference Haslam, Klein, Salter, Stoffel, Wilson, Cleary, Cooke and Thomasson1981) sky temperatures scale as the observing frequency to the power $-2.55$ (Lawson et al. Reference Lawson, Mayer, Osborne and Parkinson1987). To determine mean pulsar flux densities the integrated flux above a baseline is often computed by firstly converting the counts to Jy in a calibration procedure. The mean pulsed flux is then just the integral of the flux above a defined baseline divided by the number of bins. Millisecond pulsars can have profiles that are very complex and this makes baseline estimation difficult if using a simple boxcar, especially if it extends into the wings of the pulse profile. For every MSP, the ideal boxcar width will differ, or even require multiple disjoint sections, so we used an interactive tool to define the baseline through visual inspection for each pulsar from high S/N observations to help determine the rms of the noise in the baseline. Software was written to cross-correlate the template with each profile, and the rms residual of the phase-aligned profiles in the baseline region was evaluated.

There are sections of the MeerKAT band that are rarely affected by RFI (see Bailes et al. Reference Bailes2020), and these were used to determine the flux density in those bands. We found that many of the high-DM MSPs that would be expected to have consistent epoch to epoch flux densities often exhibited dips in their mean spectra where RFI is regularly present in the fourth of the 8 sub-bands. As an example, for PSR $\mathrm{J}1017-7156$ , the off-pulse rms was roughly 5–21% higher in this band with a mean 10% higher after our attempts at RFI removal with CoastGuard. Scaling the flux densities of all channels by the ratio of their off-pulse rms counts to that of the median off-pulse rms counts led to mean spectra largely free of this dip in channel 4 and was performed on all the data.

After integrating all of the observations for each pulsar, the vast majority of our pulsars were shown to have a smooth power law variation of mean flux density with frequency as is often seen in the population between 1–1.7 GHz, especially those at high dispersion ( ${\gtrsim} 100\,\mathrm{pc\,cm}^{-3}$ ) where strong scintillation events across ${\sim}$ 100-MHz bands are not seen (Dai et al. Reference Dai2015; see also Figure 3, showing PSRs $\mathrm{J}1017-7156$ , $\mathrm{J}1600-3053$ , and $\mathrm{J}2241-5236$ , with DMs of 94.2, 52.3, and $11.4\,\mathrm{pc\,cm}^{-3}$ , respectively). To derive spectral indices and normalise our flux density measurements to a standard frequency (1 400 MHz), we fitted a power law model, $S = S_{1400}\,(\nu/1400\,\textrm{MHz})^\alpha$ , to the mean flux density in each of 8 sub-bands across the 775.75 MHz band,Footnote n and our results are listed in Table 1. In Figure 3, we show an example of the flux density measurements and best-fitting models for 3 pulsars with varying DM values, selected for comparison with the study by Dai et al. (Reference Dai2015) on pulsars in the PPTA (Kerr et al. Reference Kerr2020).

Figure 3. Mean flux density measurements for 3 pulsars, PSRs $\mathrm{J}1017-7156$ (blue squares; $N_{\rm obs}=51$ ), $\mathrm{J}1600-3053$ (green stars; $N_{\rm obs}=33$ ), and $\mathrm{J}2241-5236$ (pink circles; $N_{\rm obs}=42$ ), fit with power law models (blue dashed, green dotted, and pink dash-dotted lines, respectively) to determine $S_{1400}$ and the spectral index, $\alpha$ . The power law models for these pulsars are: $S_{1017} = 1.09\,{\rm mJy} \times(\nu/1400\,{\rm MHz})^{-2.01}$ , $S_{1\,600} = 2.22\,{\rm mJy} \times(\nu/1400\,{\rm MHz})^{-0.99}$ , and $S_{2\,241} = 1.83\,{\rm mJy} \times(\nu/1400\,{\rm MHz})^{-3.20}$ . The error bars indicate the formal error on the means.

We refer the reader to Gitika et al. (in preparation) for a thorough analysis of the flux density measurements from these and more recent MeerTime MSP observations, and here we provide a simple comparison of our results with overlapping samples from Dai et al. (Reference Dai2015) and Alam et al. (Reference Alam2021a) to verify the accuracy of our method. Note that the Dai et al. (Reference Dai2015) spectral indices were derived from flux density measurements in 3 bands centred at 732, 1 369, and 3 100 MHz, and therefore they may be sensitive to, e.g., spectral turn-over, which is possibly seen in their analysis of PSR $\mathrm{J}1600-3053$ . With this caveat, we find good agreement between our $S_{1400}$ values and spectral indices and those of Dai et al. (Reference Dai2015), with PSR $\mathrm{J}1744-1134$ showing the greatest disparities in both $S_{1400}$ and spectral index (although the values are consistent at the 2- $\sigma$ level and this pulsar has a very small DM which makes it prone to large flux density variations). The flux density of this pulsar in the 97-Mhz sub-band centred at 1 429 MHz varied from 0.14 to 14 mJy with a mean of 3.7 mJy and a standard deviation of 4.0 mJy. Thus its difference in mean flux density is not that worrying.

Recently, the North American Nanohertz Observatory for Gravitational Waves (NANOGrav) collaboration presented a comprehensive study of flux densities for its sample with which we have significant overlap (Alam et al. Reference Alam2021a). Of the 15 non-PPTA pulsars for which we have common data, 12 had flux densities within ${\sim}$ 30% of our values and those with the largest deviations (differing by roughly a factor of 2 from our values) have low DMs. Alam et al. (Reference Alam2021a) pointed out that the median flux they obtained for PSR J2317+1439 ( $0.45^{+0.35}_{-0.19}\,\mathrm{mJy}$ ) differed from the catalogue flux density of 4(1) mJy significantly.Footnote o Our mean value 0.60(6) mJy (median of 0.37 mJy) is much closer to the Alam et al. (Reference Alam2021a) result, and we note that this pulsar scintillates strongly. The pulsar with the most observations (134 with reliable fluxes) was PSR $\mathrm{J}1909-3744$ . Alam et al. (Reference Alam2021a) measured a median flux density at 1 400 MHz of 1.03 mJy, matching our median value precisely, which gives us great confidence in our relative flux density scales. This pulsar experiences extreme scintillation events, and our measured mean flux density was 1.80(9) mJy. Dai et al. (Reference Dai2015) recorded a mean flux density for PSR $\mathrm{J}1909-3744$ of 2.5(2) mJy at 1 400 MHz. Note also that different observing strategies can lead to biases in observed flux density distributions. MeerKAT observations use a queue system with minimal intervention (and NANOGrav observations are run with minimal intervention), while observations for the PPTA are done manually, and observers are encouraged to switch sources when the source $S/N$ is low and to repeat observations when the $S/N$ is high. This leads to better uncertainties on the ToAs but biases the flux density distributions to higher values, which is consistent with our results.

Overall, we find a mean spectral index of $-1.92(6)$ , with a standard deviation of 0.6, for our sample of 189 pulsars, and we show the full distribution of spectral indices in Figure 4. This mean is consistent at the 2- $\sigma$ level with that found by Dai et al. (Reference Dai2015), who found a value of $-1.81(1)$ , as well as previous results for MSP studies (Toscano et al. Reference Toscano, Bailes and Manchester1998; Kramer et al. Reference Kramer, Lange, Lorimer, Backer, Xilouris, Jessner and Wielebinski1999) and studies of normal pulsars (Jankowski et al. Reference Jankowski, van Straten, Keane, Bailes, Barr, Johnston and Kerr2018). The typical uncertainties on the spectral indices for pulsars with ${>} 10$ observations are ${\sim}0.1$ , with 95% of the uncertainties ${<} 0.4$ . These results could be improved in future using the MeerKAT UHF and S-band receivers to increase the frequency coverage.

Figure 4. Histogram of spectral indices. In green, we show the spectral indices for pulsars with $\mathrm{DM} > 100\,\mathrm{pc\,cm}^{-3}$ (and therefore low scintillation) and those with ${>} 10$ observations to reduce the impact of scintillation on the measurements. We show the remaining spectral indices in our sample in the blue histogram.

5. Timing results

For all pulsars in this study, we list basic parameters in Table 1, and provide our measured median ToA uncertainties. The templates used for our standard timing procedure are produced from summed, temporally-integrated observations with 232 frequency channels across the 775.75-MHz band. From these high-S/N observations, we then derive pulse ‘portraits’ using the PulsePortraiture software (Pennucci Reference Pennucci2019) and produce noise-free templates with 8 sub-bands for timing.Footnote ^p We use the ‘Fourier Domain with Markov chain Monte Carlo’ (FDM) fitting algorithm from pat in psrchive to produce ToAs from archives partially-integrated to 256-s sub-integrations and 8 sub-bands across the 775.75-MHz band ( ${\sim} 97$ -MHz sub-bands). We compute ‘typical’ ToA uncertainties per pulsar by first normalising the measured uncertainties to the nominal minimum observing time, 256 s, then calculating the error on the weighted mean ToA for each sub-integration as

(4) \begin{equation} \frac{1}{\sigma_\textrm{sub}^2} = \sum_i \frac{1}{\sigma_{\textrm{sub,}i}^2} ,\end{equation}

where i represents the frequency channels, and finally returning the median of the resulting $\sigma_\textrm{sub}$ values as the typical ToA uncertainty. We note that this method approximates the ToA uncertainty achievable by proper wideband timing using a 2-dimensional template (i.e., returning a single ToA per sub-integration). We summarise the resulting median ToA uncertainties in Figure 5, showing the cumulative histogram of the median uncertainties. Note that the median ToA uncertainties should not be confused with the ultimate fitted rms residuals, as they do not factor in pulse jitter nor the deleterious effects of red noise.

Figure 5. Cumulative histogram of median ToA uncertainties from 97-MHz, 256-s sub-integrations, scaled to the full 775.75 MHz, on a logarithmic scale. From these data, 77 pulsars have sub-microsecond (median) timing precision in less than 256 s.

5.1. Timing forecast

In assembling a large dataset of MSP data across a minimum timespan of six months, we are able to determine the timing potential for each source and inform future studies. The potential for MeerTime to contribute to global efforts to detect GWs with the IPTA can be estimated from these data. As mentioned in Section 2, we continue to regularly observe pulsars that have low ToA uncertainties, $\sigma_\tau<1\,\unicode{x03BC}\mathrm{s}$ , calculated using frequency-scrunched templatesFootnote q and observations with integration times, ${256} < T_\textrm{obs}<2000\,\mathrm{s}$ .

To compare the sensitivity of PTA observations with MeerKAT to other current programmes, and its potential impact on global efforts, we consider the detection of a GW background (assuming a strain spectrum of $h_c(f) = 1.9\times 10^{-15} (f/1\,{\rm yr})^{-2/3}$ ; e.g., Siemens et al. Reference Siemens, Ellis, Jenet and Romano2013) through correlations between pulsars in the array (Hellings & Downs Reference Hellings and Downs1983). The background is chosen to be the amplitude of the apparent common red noise found in analysis of the NANOGrav 12.5-yr data release (Alam et al. Reference Alam2021b). We can approximate the sensitivity of a given PTA to both the autocorrelated signal (the ‘pulsar term’) and the cross-correlated signal (the ‘Earth term’), following Siemens et al. (Reference Siemens, Ellis, Jenet and Romano2013).Footnote r They construct matched detection statistics in the Fourier domain (see their Equation (17)) and calculate how the $S/N$ of the detection statistic depends on the noise properties of the array.

The expected $S/N$ in the autocorrelations is

(5) \begin{align} \rho_{ACF}^2 = \sum_{p=1}^{N_p} \sum_{k=1}^{N_f} \frac{P_g^2(f_k)}{P_{p}^2(f_k)},\end{align}

where $P_g(f_k)$ is the power spectral density of the GWB in frequency channel $f_k$ , where $k=1,N_f$ is a Fourier series starting $1/T_{eff}$ at the reciprocal of the common effective observing $T_{\rm eff}$ . $P_{p}(f_k)=P_g(f_k) + P_{p,r}(f_k) + P_{p,w}$ is the total power (the sum of the GWB and the red noise ( $P_{p,r}$ ) and the white noise ( $P_{w,r}$ ) in the same channel for pulsar p.

The expected $S/N$ in the cross-correlations is found as the $S/N$ of a matched filter with the Hellings-Downs correlation function

(6) \begin{align} \rho^2 = \sum_{i=1}^{N_p-1} \sum_{j=i+1}^{N_p} \chi^2_{ij} \sum_{k=1}^{N_f} \frac{P^2_g(f_k)}{P_{p_i}(f_k) P_{p_j}(f_k)},\end{align}

where $\chi_{ij}$ are the angular correlation coefficients (Hellings & Downs Reference Hellings and Downs1983)

(7) \begin{align}\chi_{ij} = \frac{3}{4} \left(1 - \cos(\theta_{ij})\right) \log \left(1 - \cos(\theta_{ij})\right) -\frac{1}{8} \left( 1 - \cos(\theta_{ij}) \right) + \frac{1}{2}\nonumber\\[5pt]\end{align}

We use the published source lists, median pulsar timing precisions, timespans, cadences, and observational parameters from the European Pulsar Timing Array (EPTA; Desvignes et al. Reference Desvignes2016), NANOGrav (Alam et al. Reference Alam2021b), and the PPTA (Kerr et al. Reference Kerr2020) to form a representative sample of the IPTA. For sources in multiple PTAs, the data set with the longest time span is used. We show how the S/N for this background increases with time in Figure 6.

Figure 6. Comparison of PTA sensitivity to the cross-correlated component of the GW background (solid lines) and the uncorrelated signal (dashed lines), using the current MeerTime timing programme with 89 pulsars (blue lines), the EPTA programme with 42 pulsars (orange lines), the NANOGrav programme with 47 sources (red lines), the PPTA with 26 (brown lines), or the IPTA as the union of the four (black lines).

For the NANOGrav sensitivity curves, we have assumed that the Arecibo timing programme ceased in 2020 August and that the pulsars are not observed elsewhere, which demonstrates the importance of Arecibo to international pulsar timing efforts. The modelling includes red noise in the sensitivity estimates, for pulsars where red noise has previously been detected (Arzoumanian et al. Reference Arzoumanian2020; Goncharov et al. Reference Goncharov2021). Undetected red noise is likely to be present in some of the pulsars timed by MeerKAT, which will affect our sensitivity estimates.

These calculations imply that the MPTA will be comparable in sensitivity to the PPTA by 2023, NANOGrav by 2024, and the EPTA by $\approx 2025$ . In less than four years, the MPTA will be contributing to the IPTA effort. As the MeerKAT timing array programme has observed a large number of pulsars from its start, the sensitivity to the cross-correlated signal (dashed lines) is always comparable to the auto-correlated signal, similar to the EPTA with its 42 pulsars. In contrast, the PPTA project includes only 26 pulsars, and NANOGrav started out with a smaller number of pulsars before gradually increasing in size starting in 2009, and, in the most recent data release (12.5-yr), they listed 47 pulsars (Alam et al. Reference Alam2021b). The MPTA could be expanded in the future with timing of additional pulsars in other bands or timing of MSPs discovered by MeerKAT and other facilities. Future work by Middleton et al. (in preparation) will examine the sensitivity of the MPTA and potential improvements.

6. Summary

In this work, we demonstrated the outstanding potential of MeerKAT for precision pulsar timing of MSPs with this initial census, analysing polarisation properties, flux densities and spectral indices, and timing precision. We presented a dataset of nearly 4 000 observations of 189 pulsars, spanning 24 months, including polarisation-calibrated profiles and high-precision ToAs. Our timing simulations offer simple predictions of future results, and we predict that the MPTA will be a major contributor to global PTA efforts within the next 5 yr. More work is forthcoming, including the first MPTA data release with full timing and noise analyses (Miles et al., in preparation), an analysis of flux density measurements for MeerTime MSPs (Gitika et al., in preparation), and a study of the sensitivity of the MPTA and potential for improvements (Middleton et al., in preparation).