3.1.1. High resolution imaging with the uGMRT

Beyond the tied-array beam localisation as detailed in Paper I, the position of SMART-discovered pulsars can be further improved via high-resolution continuum imaging with interferometric arrays, for which the high sensitivity and angular resolution of the upgraded GMRT (uGMRT) is highly appealing, provided the source is north of $-55^{\circ}$ in declination, and the spectrum is not ultra-steep (spectral index, $ \alpha \gtrsim -3 $ ). For PSR J0036 $-$ 1033, the first discovered MWA pulsar, this was convincingly demonstrated in Swainston et al. (Reference Swainston2021), for which the localisation uncertainty was significantly improved from an initial ${\sim}$ $10^{\prime}$ (i.e., discovery observation) to ${\sim}$ $10^{\prime\prime}$ through a dense-grid tied-array beam (TAB) localisation using the three different array configurations, and then eventually to $ \lesssim$ $1^{\prime\prime}$ via high-resolution imaging of the pulsar using uGMRT Band 3 and 4 (300–750 MHz) observations.

For PSR J0026 $-$ 1955, even though uGMRT observations were made in similar bands using the identical setup (i.e., concurrent visibility recording and phased-array beams), and analysed using similar procedures, imaging of Band 3 data (300–500 MHz) proved difficult due to the presence of a bright source ( $S_{400} \sim 4\,\textrm{Jy})$ in the vicinity ( ${\sim}$ $10.5^{\prime}$ from the putative pulsar position). Fortunately, our earlier observations that were made as part of the DDTC185 project (and before the realisation that the original detection was in fact through one of the grating lobes), provided significant attenuation of the source owing to the initial ${\sim}$ $42 ^{\prime}$ offset in (and hence incorrect) position. Analysis of these observations resulted in a ${\sim}$ $15\sigma$ detection, as shown in the top left panel of Figure 3, notwithstanding the fact that the pulsar was at more than half-power beam width offset from the phase centre. The resultant rms of $ 276\,{{\unicode{x03BC} {\rm Jy \, beam} ^ {-1}}} $ is nearly a factor of two larger than that was achieved with the imaging analysis of PSR J0036 $-$ 1033.

Figure 3. Upper panels: uGMRT images of PSR J0026 $-$ 1955 in Band 3 (300–500 MHz; left) and Band 4 (550–750 MHz; right), obtained from integration times of 136 and 56 min, respectively. The rms sensitivity is $\approx$ 276 $\unicode{x03BC} {\rm{Jy}}\, \rm{beam}^{-1}$ in Band 3, and $\approx$ 210 $\unicode{x03BC} {\rm{Jy}}\, \rm{beam}^{-1}$ in Band 4, respectively, yielding ${\sim} 15\sigma$ and ${\sim} 10\sigma$ detection of the pulsar. The presence of a bright nearby source (4 Jy at 400 MHz, at ${\sim} 10.5^{\prime}$ from the pulsar position) impacts the quality of calibration achievable, as seen in Band 4 observations. Band 3 observations were made at an offset position from the pulsar, and the effect of the bright source was subdued owing to attenuation of the primary beam. Lower panels: uGMRT images of PSR J1357 $-$ 2530 in Band 3 (300–500 MHz; left) and Band 4 (550–750 MHz; right), obtained from integration times of 90 and 71 min, respectively. The rms sensitivity is $\approx$ 153 $\unicode{x03BC} {\rm{Jy}}\, \rm{beam}^{-1}$ in Band 3, and $\approx$ 53 $\unicode{x03BC} {\rm{Jy}}\, \rm{beam}^{-1}$ in Band 4, respectively, yielding ${\sim}$ $6\sigma$ and ${\sim}$ $11\sigma$ detection of the pulsar. Band 3 imaging of the initial (poorly localised) pulsar position revealed multiple compact sources, one of which turned out to be the pulsar (see Section 4.1.4 for details).

The imaging of Band 4 data (550–750 MHz) benefited from a much narrower primary beam (and hence a substantially higher attenuation toward the bright, nearby source), besides a reduced flux density due to spectral index, yielding a ${\sim}$ $10\sigma$ detection of the pulsar, as shown in the right panel of Figure 3. The rms attained in this case is $\approx$ $210\,{{\unicode{x03BC} {\rm{Jy \, beam}} ^ {-1}}} $ , almost an order of magnitude larger than that is typically attainable for deep imaging of 1 h in uGMRT Band 4. This illustrates the complexity in interferometric localisation, when the imaging analysis is hampered by bright sources in the vicinity.

Table 3. Localisation summary of PSR J0026 $-$ 1955.

Figure 4. Detection summary of PSR J0026 $-$ 1955, over a ${\sim}$ 3.5-yr time span; the PRESTO detection significance ( $\sigma$ ) is plotted against the MJD of observation. The detections are predominantly from observations over a 30.72 MHz bandwidth centred at 154.24 MHz, with time integration varying from 10 min to 1 h. Note that the $\sigma$ reported for the discovery observation is for the full 80-min data that was processed for follow-up and not for the 10-min observation for initial (first-pass) search, in which the pulsar was discovered. The 3- $\sigma$ upper limits indicate non-detection in a number of 10–20 min observations.

A summary of uGMRT-derived positions are given in Table 3, along with the initial MWA-derived position. There is $\approx$ $32^{\prime\prime}$ discrepancy between the uGMRT- and MWA-derived positions, which can be possibly attributed to a residual ionospheric refraction as discussed in Swainston et al. (Reference Swainston2022a). It is possible that the $\approx$ $3^{\prime\prime} $ offset between the two uGMRT bands may also be caused by the ionosphere; even so, the final position, which we adopt as the mean of those from the two uGMRT bands, is still over an order of magnitude more precise than that reported by McSweeney et al. (Reference McSweeney2022). Further resolution to this will be possible once an improved (and fully coherent) timing solution becomes available.

3.1.2. Imaging with the MWA

For sources outside the uGMRT’s sky ( $\delta < -55^{\circ} $ ), in principle, the recorded VCS data (if available) from long-baseline configurations of the array (Phase I or Phase II extended) can be correlated offline and imaged to verify the position obtained via the TAB localisation. However, as we demonstrated in Swainston et al. (Reference Swainston2021), even with co-addition of multiple observations we were unable to reach a sensitivity better than ${\sim}$ 6–8 ${\rm{mJy}}\, \rm{beam}^{-1}$ (for Stokes I), and hence an imaging detection may be possible only for pulsars that are sufficiently bright ( ${S_{150}}\,\gtrsim\,30$ mJy). For long-period pulsars, such as PSR J0026 $-$ 1955, ‘on’ and ‘off’ gated imaging may also be attempted for improved detection in imaging, though this methodology is currently under development.

3.2.1. Leveraging archival data to achieve timing coherence

As an example of using the archival MWA data and improved positions from imaging follow-up (see Section 3.1), we are able to extract times-of-arrival (TOAs) from MWA observations alone and, in principle, phase-connect a timing solution. Here, we demonstrate that for PSR J0026 $-$ 1955 across a ${\sim}$ 1.7-yr time span.

Examining the MWA VCS observation database revealed observations containing the nominal pulsar position dating back to 2017 April, including dedicated followup observations for PSR J0036 $-$ 1033 in late-2020 into 2021. These serendipitous observations are well suited to generating a phase-connected timing solution as there was a dense observing campaign where the same field was observed 8 times in three days (2020 October 26–28), surrounded by regular observations spaced every 3–4 d for approximately 2 weeks before (2020 October 10–22) and roughly weekly cadence for one month after (2020 October 30 to 2020 November 27). Monthly cadence data were then collected until the system became unavailable for science observing (see Section 2). These observing time scales are adequate to accurately determine the rotation frequency, detect spin-down and measure the DM.

The initial rotational characteristics presented by McSweeney et al. (Reference McSweeney2022) are sufficient to fold PSR J0026 $-$ 1955 for a single observation, but quickly lose phase connection after ${\sim}$ 1 d. Using the uGMRT imaging position (Figure 3) and the initial estimates of the spin period and DM, we processed some of the more recent archival observations (two observations in 2019 April) and the majority of the PSR J0036 $-$ 1033 timing followup observations (17 observations spanning 2020 October–November), creating 10-s subintegration archives with DSPSR. These archives were then subsequently processed using PSRCHIVE routines to remove radio frequency interference (RFI), specifically using the paz median-filtered bandpass algorithm. Since PSR J0026 $-$ 1955 is a prolific nuller (cf. McSweeney et al. Reference McSweeney2022), we manually inspected each observation with pazi and masked the null subintegrations to construct a high-quality average (integrated) profile. Out of the total 21 observations, we processed for this work, 10 were excluded either due to non-detections (unsurprising for a pulsar with a $>$ 70% nulling fraction) or very weak detections (signal-to-noise ratio, S/N < 15 for the fully time- and frequency-averaged profile). The five observations with the highest S/N were then combined and artificially phase aligned using psradd and a basic frequency-averaged template was created using paas, where two Gaussian components modelled the profile.

Each observation was then pre-processed such that there were four frequency subbands per epoch, from which TOAs were extracted using the pat utility within PSRCHIVE. The initial ephemeris used to fold the observations and the TOAs were passed to both the Tempo2 (Hobbs, Edwards, & Manchester Reference Hobbs, Edwards and Manchester2006; Edwards, Hobbs, & Manchester Reference Edwards, Hobbs and Manchester2006) and PINT (Luo et al. Reference Luo2021) pulsar timing packages. With each timing package, we were able to phase-connect all available observations to the archival data points from nearly two years earlier by updating the spin frequency, adding a spin frequency time-derivative ( $28\sigma$ significance), and small adjustment to the DM. Both packages produced consistent results and uncertainties. Given the sparse sampling on longer time scales we did not fit for the pulsar sky position, however, as we accrue and/or process additional observations (with the MWA or other telescopes) we will be able to constrain the position to better than the current ${\sim}$ $3^{\prime\prime}$ uncertainty obtained from the uGMRT imaging. The current best timing solution (from Tempo2) is presented in Table 4.

Table 4. Timing solution for PSR J0026 $-$ 1955 using Tempo2.

^aThe position of the pulsar was fixed at the uGMRT imaging position, as given in Section 3.1.

4.1.1. PSR J0036 $-$ 1033

PSR J0036 $-$ 1033 is the first new pulsar discovery from the SMART survey, the details and initial follow-up of which have been reported in Swainston et al. (Reference Swainston2021). This non-recycled pulsar with a period $P=0.9$ s and a ${\rm{DM}}=23.123\,{\rm{pc cm}}^{-3}$ has a fairly typical magnetic field strength ( $ B \sim 4.4 \times 10^{11}$ G) and characteristic age ( $\tau _c \sim 67$ Myr) but has a spectral index $\alpha = -2.0 \pm 0.2 $ . An estimated luminosity at 1400 MHz, $L_{1400}$ ${\sim}$ 0.1 ${\rm{mJy}}\, \rm{kpc}^{2}$ , places this pulsar in the lowermost two percentile of the currently known population of long-period pulsars in luminosity. Its DM and a location at a high Galactic latitude ( $b \approx -72.9^{\circ}$ ) make it an excellent target for scintillation and variability studies for probing the nature of plasma turbulence in a region where it is poorly constrained. The related observations are currently under way at the uGMRT and the Five-hundred-metre Aperture Spherical Telescope (FAST) and will be reported in a future publication.

4.1.2. PSR J0026 $-$ 1955

The ‘discovery’ of PSR J0026 $-$ 1955 revealed some remarkable features of the SMART survey; most notably, the complexity of the tied-array beam pattern, resulting from a large fraction of the tiles configured as hexagonal layouts (see Paper I; Figures 7 and 8). This can result in multiple detections of pulsars through the near and far side (grating) lobes, especially when the pulsar is sufficiently bright. For instance, PSR J0026 $-$ 1955, which was initially detected as a 11 $\sigma$ candidate (in a 10-min observation) was eventually re-detected in a different pointing, almost ${\sim}$ 45 $^{\prime}$ offset from the initial position, and with a much higher significance of $\rm{S/N} = 60$ , leading to the revelation that the initial detection was in fact through one of the grating lobes.

The pulsar was also particularly noted for its sub-pulse drifting nature which became the focus of immediate investigation. Incidentally, this turned out to be an independent discovery, as the pulsar was first reported as a candidate in the GBNCC survey data; nevertheless, it was blindly discovered in our SMART processing. Further details of the pulsar, including analysis of its intriguing sub-pulse drifting and long-duration nulls, are reported in McSweeney et al. (Reference McSweeney2022).

4.1.3. PSR J1002 $-$ 2044

The discovery of PSR J1002 $-$ 2044 followed the new (revised) scheme for candidate selection and scrutiny, as described in Section 3.3 of Paper I. It is a long-period pulsar with $P=1.67$ s and a moderate $\rm{DM} = 43.172$ ${\textrm{pc cm}}^{-3}$ . The NE2001 model of electron density (Cordes & Lazio Reference Cordes and Lazio2002) places it at a distance of ${\sim}$ 1.4 kpc. Its non-detection in the Parkes 70 cm survey implies a spectral index $\alpha \lesssim -1.8 $ , and non-detections in the TGSS (TIFR GMRT Sky Survey) and NVSS (NRAO VLA Sky Survey) continuum imaging sky surveys, which reached rms sensitivity limits of ${\sim}$ 5 ${\rm{mJy}}\, \rm{beam}^{-1}$ and ${\sim}$ 0.5 ${\rm{mJy}}\, \rm{beam}^{-1}$ (in the pulsar vicinity) at their respective frequencies (i.e. 150 and 1400 MHz), implying a flux density at 150 MHz, $ S_{150} \lesssim 10 $ ${\rm{mJy}}$ . This hints at the possibility of the pulsar being another low-luminosity object, with an implied $ L_{1400} \lesssim 0.3 $ ${\rm{mJy}}\, \rm{kpc}^{2}$ , which is confirmed by our recent Parkes detection, suggesting $ S_{1400} \sim 0.1$ mJy, and hence akin to PSR J0036 $-$ 1033. The pulsar is currently being followed up for timing and localisation (via imaging) using Parkes and the uGMRT.

4.1.4. PSR J1357 $-$ 2530

Of the 120 redetections from SMART data processing (see Section 4.2), PSR J1357 $-$ 2530 warrants some additional contextual discussion. It was first ‘discovered’ in the untargetted SMART search workflow as a 6 $\sigma$ candidate in a 10-min observation, with a period (P) of 0.912 s and DM of 16.046 ${\textrm{pc cm}}^{-3}$ (see Figure 2). Follow-up processing of the full 80-min observation resulted in a significantly improved detection, with a four-fold increase in S/N, as shown in the figure. This pulsar has a small duty cycle of ${\sim}$ 2–3%, and the DM implies a distance of ${\sim}$ 0.8 kpc as per the NE2001 model of Cordes & Lazio (Reference Cordes and Lazio2002). However, a closer examination of the published literature including those from low-frequency surveys with Parkes and the Green Bank Telescope (GBT), has essentially confirmed that this is a rediscovery. The Parkes 70 cm survey appears to have been reported this as PSR J1358 $-$ 2533 with a similar period but with a significantly discrepant DM = $28\pm3$ ${\textrm{pc cm}}^{-3}$ and at ${\sim}$ 20 $^{\prime}$ offset from our MWA position (Manchester et al. Reference Manchester1996). The DM was subsequently revised upward by D’Amico et al. (Reference D’Amico1998) to $31.3 \pm 1$ ${\textrm{pc cm}}^{-3}$ . It appears that GBNCC has re-found the pulsar but with a $\rm{DM} = 16.0 \pm 0.2\,{\rm{pc cm}}^{-3}$ (McEwen et al. Reference McEwen2020). Even so, the position (and hence the pulsar’s exact name) remained uncertain and a timing solution is currently not available. The pulsar also appears to be another low-luminosity object, even if we are to assume a spectral index ( $\alpha$ ) of $-1.6$ .

In order to resolve this ambiguity, we recently undertook uGMRT follow-up observations of this pulsar (GTAC Cycle 43), where we used an observing set-up that is similar to those described in Section 3.1 (i.e. concurrent imaging and phased-array beams). Following an initial non-detection, which is attributable to a poorly localised position, imaging of the recorded visibility data revealed multiple (five) compact sources in the field within ${\sim}$ $5 ^{\prime}$ from the phase centre; one of these turned out to be the pulsar, as shown in the lower panels of Figure 3. This was confirmed in subsequent observations, where we cycled through the prospective sources by making separate phased-array beam observations. Table 5 gives a summary of the pulsar positions from our uGMRT imaging along with the initial MWA position (from the TAB localisation). The pulsar position, with R.A. 13 $^{\rm h}$ 57 $^{\rm m}$ 24 $^{\rm s}$ , and decl. $-25^{\circ}30^{\prime}39^{\prime\prime}$ , while precisely determined down to $\lesssim 0.3^{\prime\prime}$ , has a systematic offset of ${\sim}$ 3 $^{\prime\prime}$ , possibly due to ionospheric refraction (cf. Swainston et al. Reference Swainston, Lee, McSweeney and Bhat2022a). The estimated flux densities are ${\sim}$ 1 and ${\sim}$ 0.5 mJy at 400 and 650 MHz, respectively. A summary of the pulsar parameters are included in Table 2. The new position warrants renaming the pulsar to PSR J1357 $-$ 2530.

Table 5. Localisation summary of PSR J1357 $-$ 2530.

Figure 6. All-sky distribution of known pulsars in the ATNF pulsar catalogue (grey filled circles). The 120 pulsars detected in the SMART processing are shown as red filled circles, along with 57 pulsars detected from the processing of non-SMART MWA observations (shown as filled circles in dark blue, respectively, for incoherent and coherent beam detections). The black star symbols are the three new pulsar discoveries from the SMART, and the grey star is re-discovery of a previously incorrectly characterised pulsar. The declination limit of the SMART survey ( $\delta < +30^{\circ}$ ) is shown as the solid red line, whereas for surveys with other (northern) telescopes, they are shown as dashed lines at the respective lower limits in declination (i.e., $\delta > 0^{\circ}$ for LOTAAS, $\delta > -40^{\circ}$ for GBNCC and $ -40^{\circ} > \delta > -55^{\circ}$ for GHRSS).

Figure 7. Integrated pulse profiles for 120 re-detected pulsars in the SMART data processing. The period, DM, and the number of phase bins are shown in each panel. All detections were made in the SMART survey band 140–170 MHz.

4.2.1. Detection sensitivity and flux densities

The re-detections from SMART are used to ascertain the survey sensitivity at 150 MHz by comparing the measured pulsar flux densities $S_{150}^{\rm{meas}}$ with their expected values $S_{150}^{\rm{exp}}$ . To estimate $S_{150}^{\rm{meas}}$ , folded profile data were flux density calibrated using the method outlined in Meyers et al. (Reference Meyers2017). In brief, this makes use of the array factor formalism whereby the tied-array beam patterns are simulated by modelling them as the product of the tile beam pattern (primary beam response) and the array factor (in this case for the compact configuration of the Phase II array). This analysis yields estimates of the system temperature ( ${T_{\rm{sys}}}$ ) and gain (G), which are then used to estimate the system equivalent flux density, ${\rm{SEFD}} = {T_{\rm{sys}}} / G$ . The simulations also naturally take into account the strong directional dependencies of these parameters. The variability in ${T_{\rm{sys}}}$ and G over the duration of observation is accounted for as a source of error in the flux density estimate.

The expected flux densities $S_{150}^{\rm{exp}}$ are essentially based on the extrapolation from the spectral forms deduced using the published flux density measurements of pulsars. This involved the use of a large body of flux density measurements made available by Jankowski et al. (Reference Jankowski2018) as well as a number of other past publications. The model fits to the spectra are based on the algorithms described in the work of Jankowski et al. that employs the Akaike information criterion (AIC) to determine the best spectral model. Further details on the database repository and software description are presented in Swainston et al. (Reference Swainston, Lee, McSweeney and Bhat2022b). The uncertainties in $S_{150}^{\rm{exp}}$ thus largely reflect the quality and uncertainty of the model fit to the spectra (e.g., the error on the spectral index, or other spectral characteristics). An important caveat is that the bulk of the flux density measurements are from observations at frequencies $\gtrsim$ 400 MHz and as a result may likely over-predict the expected values of $S_{150}^{\rm{exp}}$ for pulsars that exhibit turnover, or a spectral break, or flattening at low frequencies.

A comparison of the measured flux densities of detected pulsars and the expected values as described above is shown in Figure 9. This includes 100 pulsars for which reasonable estimates of $S_{150}^{\rm{exp}}$ were possible (i.e., four or more measurements available to allow meaningful estimates of the spectral form and the index $\alpha$ ), which limited the analysis to ${\sim}$ 80% of the detected pulsars.

As shown in the figure, within the caveats of the uncertainties associated with $S_{150}^{\rm{meas}}$ and $S_{150}^{\rm{exp}}$ (e.g., from beam simulations, and the spectral model fits) and the assumptions involved (e.g., spectral extrapolation to 150 MHz), we find there is reasonable agreement, with the measured flux densities within a factor of two of their expected values. Evidently there are a small number of outliers where the analysis tends to over-predict $S_{150}^{\rm{exp}}$ , and this may be to do with a spectral extrapolation error. In the case of some high DM pulsars, it is also possible there may be an underestimation of $S_{150}^{\rm{meas}}$ , especially in the cases where the scatter broadening is substantial. The ratio between the measured and expected values is $S_{150}^{\rm{meas}}$ / $S_{150}^{\rm{exp}}$ = $1.05 ^{+0.42} _{-0.31}$ (after excluding a small number of outlier points where the ratio $>$ 10 or $<$ 0.1). Given this, and with the caveat that in general large flux density variabilities expected at low frequencies (as much as by a factor of ${\sim}$ 2–3 for moderate to high-DM pulsars, and even larger for low-DM ones), this provides a good demonstration that our SMART data processing is attaining a detection sensitivity in line with the expectations.

The measured flux densities of detected pulsars also validate the minimum expected sensitivity ( ${S_{\rm{min}}}$ ) for the shallow pass of our survey, where ${S _{\rm{min}}} \sim 10$ mJy for a 10 $\sigma$ detection of long-period pulsars (see Figure 9). As seen from the figure, the faintest pulsar detections are ${{S _{\rm 150} ^{\rm{meas}}}} \sim$ 7–8 ${\rm{mJy}}$ . In general, the measurements of low to moderate-DM pulsars are in better agreement compared to high-DM ones (i.e., DM $\gtrsim$ 50 ${\textrm{pc cm}}^{-3}$ ). Further details on the data used for the analysis, and the software description, are available in Swainston et al. (Reference Swainston, Lee, McSweeney and Bhat2022b).

4.2.2. Data release

Considering the inherent difficulties in accessing and processing VCS recorded data for pulsar detections and searching, we will make beamformed data of re-detected pulsars publicly accessible via a dedicated database repository (to be served by Data Central). We will adopt the preferred data format by other large pulsar databases (e.g., Hobbs et al. Reference Hobbs2011), i.e., folded archives in 10-s sub-integrations, with all 3072 channels and in full polarisation (i.e. four Stokes). For millisecond pulsars, we will provide coherently-dedispersed profiles in 1024 or more phase bins, in 24 coarse channels (1.28 MHz). Our intent is a continual growth of this database as further detections accrue from the ongoing and future data processing. Given the paucity of low-frequency pulsar detections in the southern sky, we hope this will become a useful resource, and potentially a reference catalogue of low-frequency pulsar detections in the SKA-Low era. Additionally, SMART survey raw data from 2018-2019 will be made available via a data retention project supported by Australian Research Data Commmons.Footnote b

Table 6. Known pulsars detected in SMART survey observations

^aTarget offset from observation centre.

^bLow-frequency (<400 MHz) information available in the literature: ‘M’ for MWA-incoh/MWA-image (Bell et al. Reference Bell2016; Murphy et al. Reference Murphy2017; Xue et al. Reference Xue2017; Kaur et al. Reference Kaur2019), ‘L’ for LOFAR (Kondratiev et al. Reference Kondratiev2016; Bilous et al. Reference Bilous2016; Sanidas et al. Reference Sanidas2019; Bondonneau et al. Reference Bondonneau2020), ‘W’ for LWA (Stovall et al. Reference Stovall2015), ‘G’ for GMRT (Bhattacharyya et al. Reference Bhattacharyya2016; Frail et al. Reference Frail, Jagannathan, Mooley and Intema2016), ‘g’ for GBT-GBNCC (McEwen et al. Reference McEwen2020), ‘E’ for Effelsberg (Sieber Reference Sieber1973), ‘P’ for Pushchino (Izvekova et al. Reference Izvekova, Kuzmin, Malofeev and Shitov1981; Malofeev, Malov, & Shchegoleva Reference Malofeev, Malov and Shchegoleva2000; Kuzmin & Losovsky Reference Kuzmin and Losovsky2001; Tyul’bashev et al. Reference Tyul’bashev, Tyul’bashev, Oreshko and Logvinenko2016), ‘U’ for Ukrainian T-shaped Radio telescope-UTR2 (Zakharenko et al. Reference Zakharenko2013).