Bandwidth required on cavity filter for water masers

Eduard Mol on one of the SARA meetings/online videos shows plot of W3ORS5 of water maser at 22 GHz. The plot shows LSR velocity km/s from -70 to -20 on x-axis. How does this convert into necessary bandwidth in frequency? I am ordering a cavity filter and it needs to have wide enough bandwidth.

For a water maser at 22.235 GHz (the H2O 6(16)-5(23) transition),
the conversion from LSR velocity to frequency bandwidth uses:

    Delta f / f = v / c

where:

    f = 22.23508 GHz
    c = 299792 km/s
    v = velocity relative to the Local Standard of Rest (LSR)

At 22 GHz, 1 km/s corresponds to:

    Delta f = 22.235e9 * (1 / 299792)

            = approximately 74.2 kHz per km/s


The SARA plot for W3 IRS5 shows:

    Velocity range: -70 to -20 km/s

This is a range of:

    50 km/s

Therefore the frequency coverage required is:

    50 * 74.2 kHz = 3710 kHz

or approximately:

    3.7 MHz


Minimum cavity filter bandwidth:

    About 4 MHz

However, in practice, do not order a filter this narrow because
of tuning errors, frequency drift, and uncertainty in the source velocity.


Recommended cavity filter bandwidths:

    5 MHz   - probably adequate if accurately centred
    10 MHz  - recommended practical choice
    20 MHz  - very comfortable margin


The W3 IRS5 maser emission is around -40 km/s LSR.

The frequency shift is:

    -40 * 74.2 kHz = -2968 kHz

or approximately:

    -2.97 MHz


So the maser line is approximately at:

    22235.08 MHz - 2.97 MHz

    = 22232.11 MHz


A 10 MHz filter centred at 22.235 GHz would cover:

    10 MHz / 74.2 kHz per km/s

    = about 135 km/s

which is much wider than the W3 IRS5 velocity range.


For a practical 22 GHz amateur radio astronomy receiver,
a 10 MHz cavity filter centred on 22.235 GHz would be a good choice.

When I say a 10 MHz filter centred on 22.23508 GHz, I mean the total passband width is 10 MHz, not 10 MHz either side.

So:

Centre frequency:     22235.08 MHz

Bandwidth:            10 MHz total

Passband edges:

Lower edge:           22230.08 MHz
Upper edge:           22240.08 MHz

This corresponds to approximately:

10 MHz / 74.2 kHz per km/s = 135 km/s total velocity range

or about:

-67.5 km/s to +67.5 km/s around the centre frequency

If the supplier quotes a filter as “10 MHz bandwidth at 22.235 GHz”, this is normally what they mean.

If they instead quote “±10 MHz”, then the total bandwidth is 20 MHz:

Lower edge: 22225.08 MHz
Upper edge: 22245.08 MHz

For W3 IRS5, the maser range of about −70 to −20 km/s LSR corresponds to roughly 3.7 MHz, so a 5 MHz filter could work if centred correctly. A 10 MHz filter gives useful margin for tuning, Doppler corrections, and looking at other maser sources.

Would this 10 MHz provide enough room for all water masers at 22 GHz, and enough room to accommodate velocity shift due to rotation of Milky Way and rotation of Earth around Sun?

A 10 MHz total bandwidth filter at 22.235 GHz will cover many water maser sources, but it is not enough to cover every possible Galactic water maser velocity if you want a “set and forget” survey receiver.

Let’s look at the velocity equivalent:

At 22 GHz:

1 km/s = 74.2 kHz

10 MHz bandwidth = 10,000 kHz / 74.2

                 = about 135 km/s total

So a 10 MHz filter centred on the rest frequency covers:

22230.08 MHz to 22240.08 MHz

Velocity range:
approximately -67.5 km/s to +67.5 km/s

Galactic rotation effects

The rotation of the Milky Way produces much larger shifts depending on Galactic longitude.

Examples:

  • Nearby star-forming regions: often within ±50 km/s
  • Inner Galaxy masers: can easily be +100 to +200 km/s LSR
  • Galactic centre region: velocities can exceed ±200 km/s

At 22 GHz:

100 km/s = 7.4 MHz
200 km/s = 14.8 MHz

So a 10 MHz filter will miss some inner Galaxy masers.

Earth’s orbital motion

The Earth’s motion around the Sun causes a Doppler shift up to about:

±30 km/s

At 22 GHz:

30 km/s × 74.2 kHz = 2.2 MHz

So this alone can move a source by ±2.2 MHz over the year.

Earth’s rotation

For a ground-based telescope this is much smaller:

up to about ±0.5 km/s

≈ ±37 kHz

(negligible compared with a MHz bandwidth).

Practical recommendation

For a general 22 GHz water maser receiver:

Filter bandwidthVelocity coverageComment
5 MHz67 km/sToo restrictive
10 MHz135 km/sGood for known sources
20 MHz270 km/sGood general-purpose choice
30 MHz400 km/sBetter for Galactic surveys

For your intended use (amateur radio astronomy, looking at sources such as W3 IRS5 and other known masers), I would choose:

20 MHz centred at 22.235 GHz

if the cavity filter cost and insertion loss are acceptable.

A 20 MHz filter gives:

22225.08 MHz to 22245.08 MHz

approximately -135 to +135 km/s LSR

and leaves room for Earth’s orbital velocity correction plus most Galactic star-forming regions.

If your aim is surveying unknown masers across the Milky Way, even 20 MHz may be restrictive; you would ideally want a wider preselector (e.g. 50 MHz) followed by SDR filtering.

Eduard’s plot of W49 water maser covers -20 km/s to 30 km/s. What bandwidth covers that all year regardless of rotation of Earth and Milky Way?

For W49 water maser, Eduard’s velocity range is:

-20 km/s to +30 km/s LSR

That is a span of:

50 km/s

At 22.235 GHz:

1 km/s = 74.2 kHz

50 km/s = 3.71 MHz

So the maser emission itself occupies only about 3.7 MHz.

Now add the motions you want to allow for.

1. Earth’s orbit around the Sun

The maximum barycentric correction is approximately:

+/-30 km/s

At 22 GHz:

30 x 74.2 kHz = 2.23 MHz

So allow:

+/-2.2 MHz

2. Earth’s rotation

For a fixed ground station:

up to about +/-0.5 km/s

which is:

+/-37 kHz

This is negligible compared with MHz bandwidths.

3. Milky Way rotation

This is already included in the quoted LSR velocity of W49. The LSR correction removes the Sun’s motion relative to the local standard of rest, so you do not add Galactic rotation again to the same source.

The important point is: different sources have different LSR velocities, because of Galactic rotation. W49 is around +10 km/s LSR, but another maser could be hundreds of km/s away.

For W49 specifically:

Intrinsic velocity range:
-20 to +30 km/s
= 50 km/s
= 3.7 MHz

Allow Earth orbital motion:
+/-30 km/s
= +/-2.2 MHz

Total required:
3.7 + 4.4 = 8.1 MHz

Therefore:

  • 10 MHz filter: just about sufficient for W49 all year, assuming it is centred correctly.
  • 15 MHz filter: more comfortable.
  • 20 MHz filter: gives plenty of margin.

For W49 I would centre the filter not exactly at 22.23508 GHz, but around the expected observed frequency. The mean velocity is about +5 km/s LSR, so the line is shifted by:

5 x 74.2 kHz = 371 kHz

towards lower frequency (radio convention), giving a centre around:

22,234.7 MHz

A 20 MHz cavity filter centred around 22.235 GHz would be a very good general-purpose choice for W49 and other Galactic water masers. A 10 MHz filter is the minimum I would consider.

Here is a list of bright water masers. Again, what bandwidth will cover all of these, regardless of which time of year I observe them?

G#

G208.993-19.385

G43.167+0.011

G25.649+1.050

G133.949+1.064

G92.670+3.071

G133.715+1.215

G12.681-0.182

G81.877+0.782

G49.488-0.387

G109.871+2.114

G43.795-0.127

G205.109-14.109

G10.623-0.383

G31.243-0.111

G27.184-0.082

G65.780-2.612

G269.270+37.196

G16.868-2.158

G105.370+9.841

G34.257+0.153

G63.115+0.340

G33.145-0.417

G133.694+1.216

G34.403+0.232

G81.711+0.563

G213.705-12.597

G133.749+1.198

G16.927+0.960

G25.826-0.178

G35.131-0.746

G173.481+2.446

G95.053+3.972

G106.797+5.312

G310.357+67.896

G97.312+3.282

G17.638+0.157

G69.540-0.976

G75.773+0.343

G37.821+0.412

G10.472+0.027

G59.783+0.064

G15.033-0.674

G97.525+3.182

G35.197-0.743

G158.040-21.410

G17.551-0.126

G188.796+1.033

G111.542+0.769

G173.853-13.744

G12.209-0.106

G56.370-0.634

G188.946+0.887

G28.862+0.066

G24.790+0.083

G196.454-1.677

G17.016-2.400

G168.063+0.820

G192.599-0.048

G108.595+0.492

G19.609-0.234

G107.300+5.640

G74.036-1.712

G79.977+0.816

G209.015-19.405

G210.062-19.594

G78.887+0.709

G43.237-0.046

G48.606+0.024

G31.412+0.307

G345.698-0.090

G208.898-20.050

G174.198-0.076

G154.310+21.517

G24.942+0.075

G341.218-0.212

G359.9338-17.8541

G94.603-1.796

G333.607-0.215

G105.405+9.877

G78.871+2.762

G43.816-0.117

G203.316+2.055

G0.5464-0.8511

G135.278+2.797

G30.817-0.057

G78.122+3.633

G336.994-0.027

G206.565-16.361

G208.816-19.239

G305.208+0.206

G158.347-20.556

G111.255-0.770

G300.504-0.176

G339.621-0.121

G318.022+32.811

G271.034+18.612

G188.715-2.492

G52.097+1.042

G311.643-0.380

G34.278+69.213

G81.518+0.194

G210.435-19.766

G213.879-11.829

G5.885-0.392

G23.010-0.411

G10.841-2.592

G158.768-21.577

G28.397+0.078

G35.200-1.737

G8.663+22.181

G218.054-0.116

G103.152+23.178

G45.071+0.132

G139.912+0.199

G99.982+4.170

G71.522-0.385

G14.852-0.990

G59.471-0.183

G269.153-1.128

G38.917-15.560

G320.906-0.293

G329.183-0.314

G0.1644-0.4425

G189.778+0.345

G305.363+0.213

G38.300+8.676

G108.471-2.818

G337.404-0.402

G337.419-0.160

G331.132-0.244

G311.230-0.032

G173.580+2.442

G352.158+0.403

G77.928+0.871

G108.426+0.893

G31.280+0.062

G183.721-3.664

G314.408+0.048

G170.657-0.269

G349.722+0.124

G189.053+1.069

G176.517+0.182

G264.289+1.469

G82.583+0.201

G81.897+0.812

G10.632-0.512

G100.377-3.579

G323.740-0.263

G165.472-9.059

G44.310+0.041

G328.307+0.430

G351.581-0.353

G327.402+0.444

G81.767+0.596

G357.967-0.162

G98.856+2.934

G43.124+0.033

G108.485-2.805

G353.814+0.315

G141.081-1.060

G37.554+0.201

G14.166-0.060

G31.581+0.077

G73.652+0.195

G40.494+2.541

G71.313+0.828

G36.388+0.786

G12.889+0.490

G30.547+4.721

G123.066-6.309

G331.278-0.188

G26.110-0.094

G245.438-0.147

G6.566-3.638

G41.952+0.454

G352.894+16.847

G299.013+0.128

G351.446+0.660

G333.127-0.434

G11.936-0.151

G53.184+0.159

G11.499-1.485

G37.498+0.530

G25.382-0.181

G111.618+0.830

G173.719+2.698

G21.880+0.014

G211.567-19.294

G311.719+0.240

G349.799+0.108

G109.854+2.104

G45.465+0.053

G355.130-0.302

G359.6161-0.2480

G35.578-0.030

G80.867+0.420

G30.473+5.101

G13.657-0.600

G229.570+0.150

G23.955+0.151

G32.744-0.076

G278.588+52.479

G111.524+0.801

G117.686+4.104

G48.709-4.778

G78.937-2.717

G31.584+5.377

G337.860+0.271

Data from MaserDB https://maserdb.net/

For this list, the answer is quite different from the W49/W3 examples because you are no longer asking about one source — you are asking for a single fixed cavity filter that can observe any bright Galactic water maser at any time of year.

The key quantity is the LSR velocity range of these masers. The Galactic longitude/latitude names alone do not give the velocity; we need the measured maser velocities from MaserDB. However, from the distribution of these well-known Galactic H2O masers we can estimate the required range.

Contributions to the required bandwidth

At 22.235 GHz:

1 km/s = 74.2 kHz

1. Galactic maser velocities

The bright masers in your list include:

  • Outer Galaxy sources (negative LSR velocities, often -100 to -20 km/s)
  • Local arm sources near 0 km/s
  • Inner Galaxy sources (positive velocities, sometimes +100 to +200 km/s)

A realistic envelope for bright Galactic star-forming water masers is approximately:

LSR velocity:
-150 km/s to +200 km/s

That is:

350 km/s total

Frequency span:

350 × 74.2 kHz

= 26 MHz

2. Earth’s orbital velocity

The Earth’s orbit changes the observed velocity by:

+/-30 km/s

Equivalent bandwidth:

30 × 74.2 kHz

= 2.2 MHz each side

= 4.4 MHz total

3. Earth’s rotation

Maximum effect:

<1 km/s

<75 kHz

Negligible.


Total required bandwidth

A realistic calculation:

Galactic maser velocity range:
350 km/s       = 26 MHz

Earth orbit allowance:
60 km/s        = 4.5 MHz

Total:
410 km/s       = about 30.5 MHz

So:

Filter bandwidthSuitability
10 MHzNo – only covers a subset
20 MHzCovers many, but misses extreme velocities
30 MHzProbably adequate for your list
40 MHzComfortable all-sky Galactic coverage
50 MHzVery safe survey bandwidth

My recommendation for your 22 GHz system

If the cavity filter is intended mainly for:

  • W49
  • W3 IRS5
  • Orion KL
  • other famous bright masers

then:

20 MHz is sufficient.

If the goal is to use your dish as a survey instrument and observe any source from MaserDB, I would choose:

40 MHz bandwidth centred at 22.235 GHz.

That gives:

22.215 GHz to 22.255 GHz

Velocity coverage:
approximately +/-270 km/s

which covers essentially all known Galactic star-forming masers and leaves room for the Earth’s annual Doppler shift.

One further point: at 22 GHz the cavity filter does not need to be extremely narrow because the SDR (for example an SDRplay/ADALM-Pluto/USRP) can do the final channel filtering. The cavity filter’s main job is usually front-end protection from out-of-band signals and improving LNA dynamic range, so a wider, lower-loss filter is often preferable.

By Admin

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