First light for AG14 and 10 Micron test report- Part 1

First light for the OOUK (Orion Optics UK) AG14. The Veil Nebula is a cloud of heated and ionized gas and dust in the constellation Cygnus. It constitutes the visible portions of the Cygnus Loop, a supernova remnant, many portions of which have acquired their own individual names and catalogue identifiers. The source supernova was a star 20 times more massive than the Sun which exploded between 10,000 and 20,000 years ago. At the time of explosion, the supernova would have appeared brighter than Venus in the sky, and visible in daytime. (Courtesy Wikipedia)

A number of “first lights” and test reports will be coming up in the next several weeks as I continue to reshuffle equipment around and acquire some new gear!

Cave Astrola 10″ newtonian, pictured as it was around 2010 or so. First telescope I owned from age of 13 and the only scope I had until I moved out to NM 10 years ago!

Let’s start with the telescope. I have always been a fan of the classic Newtonian telescope since the days of my old Cave Astrola! Hard to beat the crisp star images with their beautiful diffraction spikes. I think these add tremendous depth to an image. Of course I have a couple of small refractors too but on a bigger scale the Newtonian wins out. They are also much less expensive to produce. The “Newtonian” reflector was designed by Sir Isaac Newton and he completed his first telescope in 1668! It has to be the simplest optical design with just one primary parabolic mirror and one secondary flat mirror. Many amateurs make their own newtonians and these are really great scopes!

Newtonian optical design. Arrows show light coming into the telescope from space. ‘P’ is the primary parabolic mirror, ‘S’ is the secondary flat mirror which reflects the light out of the side of the tube. The light passes through a “corrector lens” C just before it enters the camera

The basic design has not really changed much except for modern telescopes designed for astrophotography the secondary mirror is larger to improve illumination at the edges of the field and focal length or the point where light comes to focus is much shorter than it used to be. The advantage to that is that you can capture the same amount of light in a much shorter amount of time while producing a much wider field of view. Astrophotographers often refer to this type of optics as “fast”. So for example my old Cave Newtonian had a focal ratio of 7 which means that for a 10 inch mirror the focal length was 1750mm or 250mm x 7. This is considered an intermediate length. The new 14” or 350mm scope has a “fast” focal ratio of 3.8. That means the focal length is 1330mm despite the fact the mirror diameter is 4” greater!

Images showing the aberration called “coma” on the left and how a corrector lens can correct the deformity on the right. “RCC” stands for “Rowe coma corrector” which is a particular brand of corrector lens, not the one I am currently using

Historically the faster Newtonians had issues with star deformities along the edges of field called “coma” where the stars look like small comets (see above image). The basic parabolic mirror surface is able to reflect all rays of light to a single point but as the F number decreases this property seems to breakdown some. The advent of modern “corrector lenses” with multiple optical elements has reduced this problem to almost nil. The lens is placed just in front of the camera.

The telescope is a native f/4 but with a 3″ Wynne corrector it becomes an f/3.8. Here the corrector is shown placed into the focuser. The corrector position has to be adjusted manually until focus is properly reached

Mounted AG14 newtonian without camera. Despite short focal length it is still about a 4 foot long tube.

Front view of scope showing secondary mirror in the foreground, primary at the back. The secondary support “vanes” are what cause the 4 diffraction spikes in the star images.

AG 14 fully loaded with Optec Leo focuser and SBIG STXL 16200 camera. Total weight is probably close to 10 pounds or so. That’s the one downside to this design. It is a very eccentric load to have all that weight hanging off to the side like that so accurate balancing, tracking etc are more challenging to achieve

The Orion Optics 14” Newtonian astrograph is manufactured in the UK. They are all hand built with “extreme precision” so they say. Like everyone looking to purchase something like this I did my research and of course looked at the images obtained. Needless to say the image quality I have seen for these is outstanding. The market for Newtonian scopes larger than 12” is fairly limited right now. OOUK (Orion Optics UK) has a pretty solid track record. A couple of features besides the mirror quality that I liked was one: their usage of carbon fiber optical tubes. These are very resistant to temperature changes and are extremely rigid and light weight.
The second feature I liked was this: there can be some small yet irritating effects created on long exposures of objects on these scopes which may have a bright star in the field. This effect, if not corrected, can detract from a perfect image of stars and give a little roughness to the star’s edge. It is caused by microscopic ground pits around the extreme edge of the chamfer of the primary mirror which can disturb ever so slightly the light and create this problem. I saw it on my old Newtonian. To counter act this small problem, the mirrors at OOUK are produced with a circular field stop placed around the chamfer of the mirror, so that is another plus.

It took about 15 months for the telescope to arrive! The company was shutdown for half a year because of COVID. At any rate assembly for this once it arrived was pretty straightforward. They shipped the primary mirror separate from the optical tube. The primary is housed inside a “mirror cell”.

The AG14 mirror cell. A 9 point, nylon66 tipped suspension system spreads the ‘load’ of the mirror as evenly as possible over those 9 points at the back of the mirror.

Back of the primary mirror showing collimation screws and mirror fans . There are 3 pairs of screws. The smaller outer screws are the locking screws while the inner screws are the collimating screws

The best optics in the world can be literally ruined unless they are supported correctly in a telescope’s body. Finely hand figured surfaces, no matter how good they are, will not give their best unless the mirrors have a firm but resilient method of holding the mirror.
Shown above is the mirror cell which has machined, anodized aluminum surfaces. Anodizing adds a protective layer to the aluminium which gives the aluminium protection against corrosion and also produces a harder surface which reduces the risk of scratches or wear in the threaded holes. The cell also has 3 fans for cooling, indispensable for this type of optic.

Assembly basically consisted of placing 6 screws through the optical tube into the cell. The cell actually “snaps” into a support ring in the tube so all you have to do then is rotate the tube until the screw holes line up. One person can do this although just to be safe I had my wife help me out 😊
Of course the telescope comes with tube rings for mounting but I did have to order the mounting plate as an extra. The optical tube assembly weighs about 40 pounds which isn’t bad considering the size.

Next step was putting the telescope on the mount, which I will discuss in the next post, and then collimating the optics. Collimation is the process of aligning the mirror elements in your optics so the light truly does arrive at a single focus point. Both the primary and secondary have collimation screws. In this case the secondary alignment was fine and it was only the primary that needed adjusting. I have a fair amount of experience collimating Newtonian optics over the years and have been accustomed to a “two step” approach. First is alignment using a device known as a “sight tube” with cross hairs which can be done during the day and the second step is fine tuning at the telescope with a software program.

Sight tube with cross hairs used for collimation from catseyecollimation.com The CATSEYE line of “telescoping” sight tubes feature tuneable “length” capability depending on your scope’s focal length

Fine tuning collimation involves use of the popular software CCD Inspector from CCDware. The workflow is first, center a star of suitable magnitude that won’t saturate with let’s say a 1-3 second exposure, defocus the star, take an image and turn the collimation screws to move the star in the direction of the arrow, then re-center the star and repeat the process. I was able to reduce the initial error of 16 arc sec to around 3 arc sec average. Best single result is shown here, 0.9 arc sec. A full post was devoted to the detailed use of CCD Inspector single star collimation here

I decided on the Optec Leo focuser (above images) for this setup. The folks at OOUK did customize the mounting base for this focuser. It is very low profile and one nice feature is an adjustable “split clamp tube” that you can change the position of the Wynne corrector lens which you can see is very large. This eliminates the potential need to figure out additional adaptors to reach focus.

First light for AG14. The Veil Nebula is a cloud of heated and ionized gas and dust in the constellation Cygnus. It constitutes the visible portions of the Cygnus Loop, a supernova remnant, many portions of which have acquired their own individual names and catalogue identifiers. The source supernova was a star 20 times more massive than the Sun which exploded between 10,000 and 20,000 years ago. At the time of explosion, the supernova would have appeared brighter than Venus in the sky, and visible in daytime. (Courtesy Wikipedia)

Finally putting it all together, a “first light” image! This is a raw 10 minute guided red filtered image of the Veil nebula. The gibbous moon was very bright so the filtering I felt was necessary. I do not see any coma or any major deformities throughout the full field. There might be a slight adjustment needed on the focuser centering as at full resolution a couple stars show a hint of double diffraction spikes but overall it does look like the 16 megapixel APS-C size sensor is a good match for this scope! Slight guiding issue likely due to my 4 arc minute polar alignment error. More on this in the next post.
Overall I think the AG14 has definite potential. It’s still a little early to put a definite rating on it but so far I like what I see!

Next up, the 10 Micron GPS 2000 mount test report!

Thanks for reading!

DrDave

Observatory News!

James Webb Space Telescope first image of galaxy cluster SMACS 0723

I would be neglecting my blogging responsibilities to leave out the monumental breakthrough in space science and exploration which is the James Webb Space Telescope! The first images came online a couple of months ago beginning with this mind blowing image of SMACS 0723, a galaxy cluster in the Southern Hemisphere as viewed from Earth. The region of sky is about the size of a grain of sand! The galaxies in the foreground are seen at a distance of 4.6 billion light years. It is the twisted and curved galaxy images, that appear from behind the cluster due to gravitational lensing, that are much much further out, on the order of 13 billion or so light years. This is “shortly” after the universe’s beginning. For more on this image see https://www.nasa.gov/image-feature/goddard/2022/nasa-s-webb-delivers-deepest-infrared-image-of-universe-yet

Leo Galaxy Cluster taken not long ago with my Tak 180 ED. About 2% of the distance covered by the JWST!

Not long ago I captured this image of Abell 1367, the galaxy cluster in the constellation Leo. This cluster is about 330 million light-years distant in the constellation Leo, with at least 70 major galaxies. The elliptical galaxy known as NGC 3842 is the brightest member of this cluster. This is seen to the left and slightly upward of the center of the image. Of course the distance here is only about 2% of what is covered by the James Webb! No gravitational lensing here 🙂

On to darker pastures

NOT a rock concert but sadly the actual current nightly view from Orion’s Belt Remote Observatory to the valley below which is maybe 150 yards

It is hard to believe that this area has basically collapsed in the last 6 years to this! When we first moved out here there was nothing. Then developments started to sprawl east of the town of Cloudcroft and pretty much blew up anything astronomy related. I guess it’s not totally surprising since there is only one decent sized road that goes right through here but it is curious that it came so quickly. At first I was kind of in denial thinking that it still wouldn’t affect the actual images, ..until it did! I was up here one night recently imaging with my new CMOS camera and noticed sky glow for the first time. I confirmed it was actually one of the security lights down there when it briefly was turned off, the sky glow went away!

Arrow points to the well known “New Mexico Skies Astronomy Enclave”. Buyer beware!

It would seem that whatever lighting ordinances are in place in this area are not being enforced. Anyway I’m out, and moving all of my stuff to “darker pastures”. Of course this means we are going to be saying goodbye to what was a lifelong pursuit, to build and operate a remote observatory. It was a great run and an awesome time but life goes on!

On to Pie Town, NM

We’re currently in transition preparing two of my rigs for the move to Pie Town NM, located in the Northwest part of the state about 4 hours from here. I drove out there over a year ago to check it out. It’s probably in one of the most remote regions of the State. Bortle 1-2 skies and average seeing is around 1.5, a full arc second better than here. More details on the area can be found here

Roll off roof completed for the 16″ scope! The semicircular design allows for safe closure of the roof regardless of telescope park position

Skypi Observatory in Pie Town is a relatively small telescope hosting site where the owners are quite passionate about their observatories as you can see! I will have two separate observatories for each of the telescopes I move out there.

Front view of observatory

Move in date is probably going to be some time in early October.

New addition to the “fleet”!

Meanwhile I have been setting up a second platform to go out to SkyPi. This is a 14″ imaging newtonian from Orion Optics UK. The mount is a 10 Micron GM2000 which I have never used before. I am traditionally a Software Bisque user since the early 2000s but I have had some concerns over recent quality and customer service issues. Anyway this has been a very interesting journey so far! I am using the Pier 1 in my current observatory to do the testing.

First step was drilling and tapping for the M6 bolts needed to mount the 10 Micron adaptor. There is a convenient arrow which you can see on the right that points to the pole. I used the Software Bisque pier that had the Paramount and 16″ scope mounted on it

The mount has bolts which thread into the adaptor plate

Scope assembled with Optec Leo focuser and SBIG STXL 16200 camera

The telescope is a native f/4 but with a 3″ Wynne corrector it becomes an f/3.8. Here the corrector is shown placed into the focuser. The corrector position has to be adjusted manually until focus is properly reached

Back of the primary mirror showing collimation screws and a central 12V outlet for the three mirror fans

Rough collimation of the optics with a sight tube. Probably pretty close but we will see!

From the macro to the micro

Two other scopes that I have used up here including the Tak180 ED and FSQ106N are being transitioned to portable set-ups that I can travel with. My wife and I plan to use a small RV where I can go to any dark site I wish!

That’s all the news for now!

Thanks for reading!

DrDave

New image- Rosette Nebula

The Rosette Nebula (also known as Caldwell 49) is an H II region located near one end of a giant molecular cloud in the Monoceros region of the Milky Way Galaxy. The open cluster at the center of the nebula, NGC 2244 (Caldwell 50), is closely associated with the nebulosity, the stars of the cluster having been formed from the nebula’s matter.
The cluster and nebula lie at a distance of 5,000 light-years from Earth and measure roughly 130 light years in diameter. The radiation from the young stars excites the atoms in the nebula, causing them to emit radiation themselves producing the emission nebula we see. The mass of the nebula is estimated to be around 10,000 solar masses. (courtesy Wikepedia)

In this “narrow band” image three filters are utilized to capture the emission components of the nebula: Sulfur, Hydrogen and Oxygen. In contrast to usual broad band imaging where your red, green and blue filters cover each about 100 nanometers of wavelength, these three filters each allow only 3nm of wavelength transmission! Because of this the RGB or red, green and blue have to be “color mapped” to create a color image. This is also referred to as “tone mapping”. In other words, it is false color. Both sulfur and hydrogen emit light in the red portion of the spectrum whereas oxygen is blue-green. Back “in the day” which was the early 2000s, the Hubble Heritage Team which was responsible for producing color images from Hubble telescope data, also narrow band, came up with the “S-H-O” or “Hubble palette” for color . In this scheme, Sulfur is mapped to red, Hydrogen is mapped to green and Oxygen to blue. For amateur systems this creates an interesting dilemma because hydrogen is by far the strongest signal so images are typically overwhelmed with green which is not exactly the most aesthetically pleasing for astro-images. However contemporary processing software allows one to create just about anything they wish in terms of color. It’s pretty much the wild wild west as far as that goes! This particular image here is a pretty standard “Hubble palette” with some of the green “dialed down” 🙂 For more on narrow band imaging, see this post

Full resolution version of the above image can be found by clicking on the thumbnail under “My astroimages” on the lower right of this page

Capture info:
Location: Mayhill, NM
Telescope: Takahashi FSQ106N
Mount: Paramount MX+
Camera: SBIG STXL16200
Data: S-H-O 12,7,10 hours respectively
Processing: Pixinsight

Thanks for reading!

DrDave

Parade of Planets

From lower left to upper right: Jupiter, Venus, Mars, Saturn (right next to the right border of the image)

This month several planets are visible simultaneously in the dawn sky! The image above was taken at around 5:50 MDT from Las Cruces NM. From lower left to upper right are: Jupiter, Venus, Mars and Saturn. Don’t miss the solar system parade the rest of this month! On April 27th the waxing Moon will joint the party and on April 30th a conjunction of Jupiter and Venus will occur where they appear to merge together into one bright spectacular glow! A conjunction is a celestial event in which two planets, a planet and the Moon, or a planet and a star appear close together in Earth’s night sky. Conjunctions have no profound astronomical significance, but they are nice to view. In our Solar System, conjunctions occur frequently between planets because the planets orbit around the Sun in approximately the same plane – the ecliptic plane – and thus trace similar paths across our sky. (courtesy nasa.gov)

Planetary “parade” on morning of April 22

Illustration of what I saw earlier this morning, from the ‘Stellarium’ planetarium program, looking East at around 5:50 AM or so. But wait, there is another! Yes, Neptune is also crashing the party as you can see, but you do need binoculars and it has to be dark in order to see Neptune.

Don’t miss the parade!

Thanks for reading!

DrDave

Astronomy Picture of the Day!

First image featured on the APOD site! It’s a fascinating field and I tried to capture what it looks like in a typical binocular view. I do have a blog page devoted to it which you can find here New Image: Open Clusters in Puppis

For the full write up on the APOD site, here is the direct link APOD.

For the full resolution version click on “My Astro-images” to the right of this page and lower down. You will see the thumbnail on the Flickr site.

Thanks for reading!

DrDave

New Image- Distant Fireworks!

NGC 6946, sometimes referred to as the Fireworks Galaxy, is a face-on intermediate spiral galaxy with a small bright nucleus, whose location in the sky straddles the boundary between the northern constellations of Cepheus and Cygnus. Its distance from Earth is about 25.2 million light-years , similar to the distance of M101 (NGC 5457) in the constellation Ursa Major. Both were once considered to be part of the Local Group , but are now known to be among the dozen bright spiral galaxies near the Milky Way but beyond the confines of the Local Group. NGC 6946 lies within the Virgo Supercluster.
Discovered by William Herschel on 9 September 1798, this well-studied galaxy has a diameter of approximately 40,000 light-years, about one-third of the Milky Way’s size, and it contains roughly half the number of stars as the Milky Way. It is heavily obscured by interstellar matter due to its location close to the galactic plane of the Milky Way. Due to its prodigious star formation it has been classified as an active starburst galaxy. (Courtesy Wikipedia)
An H II region is a region of interstellar atomic hydrogen that is ionized. It is typically a cloud in a molecular cloud of partially ionized gas, with a size ranging from one to hundreds of light years, in which star formation has recently taken place. These can be seen in distant spiral galaxies as red-pink star-like “knots” in the spiral arms, several of which are evident in this image. These HII regions are enhanced with data obtained using a hydrogen- alpha filter.

Capture info:
Location: Orion’s Belt Remote Observatory, Mayhill NM
Telescope: Officina Stellare RiDK 400mm
Camera: SBIG STX 16803
Mount: Paramount MEII
Data: LRGB HA 5,6,4, 5,5 hours respectively
Processing: Pixinsight 1.8.8-11

Full resolution version can be seen at right under “My Astroimages”

Location of the Fireworks Galaxy shown by the blue square (Courtesy Stellarium). The constellation Cepheus is left and Cygnus is lower right highlighted by the bright star Deneb. Currently the galaxy is visible just before sunrise. The galaxy is dim at close to 10th magnitude so you will need at least a medium sized telescope to spot it as a fuzzy patch, in a fairly dark sky 🙂

Thanks for reading!

DrDave

New Year Dawning

Sunrise over Las Cruces NM Dec 29, 2021

As 2021 comes to a close and we reflect on the year, a few events stand out:

The Mars Rover lands!

Road trip to Pie Town

RS Ophiuchi variable star blows up!

Live outreach returns!

High resolution spectroscopy for the astroimager

New Mexico Skies takes a major hit

A few image publications along the way

As the New Year dawns we already have a new space telescope, the James Webb, on it’s way out to the deployment point beyond the Moon, and what looks like another amazing naked eye comet . On the personal front 2022 will bring many changes and new adventures! Stay tuned.

Happy New Year and thanks for reading!

DrDave

Observatory News

New Mexico Skies gets downgraded!

In perhaps a not totally unexpected development, the Clear Sky Clock, which is an often-used resource amongst astronomers in North America, has officially downgraded the sky conditions with respect to light pollution for New Mexico Skies. Since the early 2000’s this mecca for remote imaging worldwide was about as dark as it could possibly be. As long as I can remember it was always a Bortle 2 sky (on a 1-9 scale) where the absolute darkest places on Earth are a Bortle 1. Recently I went on the website and I noticed something odd. The color-coded bar for light pollution is no longer black. It’s blue, meaning it is now officially a Bortle 3 sky! (Rural sky as opposed to dark site). What this means practically for observing and imaging is that there are now one or more light domes extending up to about 10-15 degrees of altitude where before there were none! I am starting to see more sky glow in my images than I noticed before. I actually had wondered when this would happen because since I set up here 5 years ago I have seen a lot of growth along the access road and right here in the valley, ranchers have come in and set up shop with a bunch of security lights, outbuildings, new homes etc. You wonder how much longer it will be before there is no longer any advantage to being up here. It will soon become the age of the traveler where the only way you can have access to a truly dark sky will be to travel to one. I predict one day, maybe sooner than we think, permanent amateur installations with the exception of those in or around professional observatory sites (e.g. Chile) will no longer be desirable. Sad.

Clear Sky Clock for New Mexico Skies showing the light pollution color bar is now blue

Bortle 1-3 zone where Bortle 3 becomes rural as opposed to dark (see link above to Wikipedia page). Light domes are now visible up to 10 -15 degrees

This is the actual observatory location. It may be difficult to see the small “finger” of dark blue encroaching into the grey zone, like a cancer. To the lower left is El Paso Texas

Scope sensors installed

I decided to install these finally after an incident occurred where the roof spontaneously closed after a computer reboot! Apparently there is a “safety feature” built in to the roof controller where if there is a computer shut down for whatever reason and the roof app closes, a command gets sent to the roof controller to close the roof. Well what happens if your scope is not parked? Disaster of course! I have set up my piers very tall so I can see more of the sky but because of that the telescopes have to be parked flat in order for the roof to close. The roof system is called Skyroof from Interactive Astronomy and I have posted on this a few times. They have a scope sensor system that can easily plug in to the main control board. They were able to customize a set up for two scopes being used simultaneously. With this system installed the roof cannot close if either scope is unparked!

Scope sensor configuration as viewed from the observing space. The photo cells are placed on the west and east observatory walls. These input to a master circuit board mounted over the warm room. The board connects to the roof controller in the warm room

Master control board mounted over the warm room. You can see the inputs from both west and east photo cells “w” and “E”

This is one of the mounted photocells. Amber light means the reflecting tape is detected and the scope is parked. If the beam is interrupted, i.e. the scope is not parked, the light changes to red

Scope sensor connection to the roof controller in the warm room, blue and yellow wires circled

Reflecting tape placed on the refractor on Pier 2. I have it mounted on the dew shield with gaffer’s tape which does not leave any residue. The photocell detects the reflecting tape to register the system as “parked”

Sky Roof app is open showing the scope is parked. The roof can now open or close

At least one of the scopes is unparked. The roof will not close.

New project on Pier 2. Pier 1 in transition

Pier 1 is temporarily shut down until the 400mm scope gets packed up and prepared for the move to SkyPi observatory in Pie Town NM. This probably will start in Jan-Feb. The actual move won’t be until May or so. The equipment on Pier 1 will be replaced with a 350mm imaging Newtonian.
Pier 2 is still fully operational and currently a project has been started on NGC 1333. This is a stellar nursery featuring a fantastic reflection nebula, in the northern portion of the constellation Perseus!

Single raw luminance image of NGC 1333. Doesn’t look like much right now but check back in a month or so!

That’s about all the news I have for now!

Thanks for reading!

DrDave

High Resolution Spectroscopy for the Astro imager: Why , What and How

Hi folks! I know it’s been awhile since I’ve been on here. Back to work full time… for awhile anyway. However I had a chance to do a presentation on amateur spectroscopy for the Astro imaging channel (also known as TAIC) on Youtube this past Sunday.

You can see the presentation in its entirety right here: https://www.youtube.com/watch?v=e3wZos5CMC0

Hope you enjoy it!

As always, thanks for reading!

DrDave

New image: Soul Nebula

The “Soul Nebula”, more commonly designated by the cluster “Index Catalog” number IC 1848, is a large star forming region toward the constellation Cassiopeia that contains several small open star clusters. The Soul Nebula is about 100 light years across and has an estimated age of 1 million years. It is formed by the stellar winds from the stars embedded within it, a process that leaves behind large pillars of material pointing inwards. These pillars are very dense and have stars forming at their tips. Each pillar spans about 10 light years.

Capture info:
Location: Orion’s Belt Remote Observatory, Mayhill, NM
Telescope: Takahashi 180 ED reflector
Mount: Paramount MX+
Camera: SBIG STXL 16200
Data: 4, 3.5, 4.5 hours RGB respectively
Processing: Pixinsight

Annotation version showing the location of the open cluster IC 1848 and the small emission nebula IC 1871

Above image shows the location of the Soul Nebula in the northeast sky, northern hemisphere, around 10PM MDT. The blue square shows it’s position just below the constellation Cassiopeia and above and to the left of Perseus. A sign of summer’s ending and autumn beginning! The September Epsilon Perseid meteor shower is active from September 5 to 21, with a peak of activity occurring around September 9. Unlike the August Perseids, the September Epsilon Perseids are not caused by the comet 109P/Swift-Tuttle. Presumably, the parent body of the Epsilon Perseid meteors is an unknown long-period comet. It’s not a particularly noteworthy display. Only about 5 or so meteors per hour are typical.

Thanks for reading!

DrDave