We left Wayland on Tuesday the 13th....raining, but with two tractor trailers filled to the brim - the 40' and the 53'!

We followed the little one and 4 firefighters from Ashby followed the big one to North Haven where we made a driver change - unions !!! Following these trucks thru Queens and Brooklyn was something else!

 

Our FDNY escort was waiting with lights flashing to take us over the bridge - the Rockaways - to Breezy Point. The sheer number of emergency vehicles was mind blowing, but none belonged to FEMA or the Red Cross!!! Mostly fire and National Guard, back hoes, front end loaders, fire hoses everywhere, and destruction everywhere.

 

This is a beach community made into a year-round community because fire, EMT's, and police have to live x number of miles from their assigned station and costs were off the wall....so the Rockaway area is now a year-round part of the city. Only problem is that the homes are on slabs or 2-3 foot foundations, and were swept aside by 15' storm surge - BOOM, and they were 100' from where they belonged - one house was split in two, and on the second floor the bed was still made ~ it looked more like tornados mixed with fire and up to 8' of sand left behind.

 

While the Guard emptied our mother lode, our firefighter Sean took us down to walk the beach....not near the fire, as it's still under a state of emergency, but passed the Army hummers parked on the sand....low tide is over a 1/4 mile from homes and its flat.....you can picture the water coming toward you! We walked for a least a mile, some homes completely not there, just a piece of fence and a house number written in the sand - 206 I remember! Broken everything, everywhere and this was two weeks after the storm...huge piles of stoves, water heaters, car parts, stereos, furniture bits, then a house pretty much intact, but 6' of sand throughout...

 

No private companies allowed at that point - no water, no gas, no electric, no tools - you could see where everything we brought could and would be used. No insurance people in either...these people felt forgotten, and they had been.

 

David wants to go back Christmas Eve with nothing but toys, but we need to see what will help them most....kids doing badly as many are still not in school - well they're living there, but no teaching is being done! They are so displaced and sad... all their "things" are gone and you know how much covet their treasures.

 

Steve, please know that every single thing you and Spencer brought was in good hands within 2 days...everything was gone!

 

Only thing they don't need is clothing...now I need to know what and when!

 

Hope you all had the best Thanksgiving.

 

Big hugs and a ton of thanks.

C.

This was born yesterday, but we now have a 40 footer to take new toys to Breezy! They have an old traditional Christmas tree lighting that the entire community attends, and celebrates. When I called my civilian liaison, Theresa, yesterday she told me of the party then mentioned they had nothing to give the kids as holiday presents!!!

 

Their need has been for things to survive, but now it's time to care for the kids!

 

We are leaving Wayland on Friday, December 14th at 8am...hopefully with the 40' full of gifts, unwrapped.

 

We placed a maximum amount of $20.00 -$25.00 per gift. We didn't want to see one bike, or an IPhone show up...this way everything will be pretty much equal.

Suggestions only:

Age groups:

0-2 years            stuffed animals

3-6 years            Fisher - Price, and  Cabbage Patch  Dolls

7-9 years            Lego's - Barbie for the girls

10-13 years        Lego's

14+                   Sport's Equipment- footballs, baseball equipment(gloves, balls and bats), soccer balls and several portable nets

 

Two things to remember NO SPORTS TEAM LOGOS on sports equipment. These kids have absolutely nothing. NOTHING THAT REQUIRES ELECTRICITY, they have none!

 

Sports equipment works for all ages from 6 on...they are all very involved in sports.  We were even thinking that several of those movable basketball hoops would be great.

 

You and Spencer were so wonderful with our first load, we'd love it if you could spread the word for this Holiday trip!

 

Yes, we'll take checks - made payable to Cynthia Hill ~ I'll happily go shopping for these children who have no idea we're coming!

 

Steve and Spencer, thank you from me and from our Breezy Point friends. They really can't believe people care about them...

 

Read the attached Letter to the Editor!

 

Huge hugs,

Cynthia

A journey to Breezy Point

To the residents of Wayland, and surrounding communities, the residents of Breezy Point NY, thank you.

They thank you for the two tractor trailer loads filled to the brim with generators, space heaters, work gloves, shovels, 22 wheelbarrows, pallets of bleach, electrical cords, boots, winter clothing for men, women and kids, diapers, pallets of paper towels and toilet paper, antibacterial gel, pet food, and so much more.

You loving brought cars, SUV's, and trucks full of necessities for our neighbors in New York who had nothing left after Hurricane Sandy. Stop & Shop, just days before they opened, not only donated the trucks, but drivers, gas, and their employees to help you unload your car...the General Manager, Mike Bussell, saw people in a horrific mess and along with his corporate team, when to work...he even made sure pallets of drinking water were in both trucks. Mike, also a volunteer Chief with the Ashby Fire Department, knew what these people needed after water, fire and up to 6 feet of sand swept away part or all of their homes.

I wish you could have seen the faces of the FDNY, National Guard and civilian volunteers as those huge trucks pulled in to an area still under a State of Emergency...we lifted the doors and people started to cry. With destruction everywhere they couldn't believe people cared about them....

A woman came up to me and told me I was her angel - I'm sure a few in town would disagree - now she could begin to dig out her house. I certainly wasn't her angel but I could hug her and let her know that so many wonderful people cared what happened to her, that we'd be there for Breezy.

The people of Breezy Point are a strong, proud and caring community, but looking around me, I couldn't imagine what courage it would take to keep going day after day.

It's been almost a month now ~ Breezy still has no electricity and all must leave before dark. You've probably heard about the looting, Theresa tells me it's not too bad. What do you mean "not too bad" I shouted to myself, you've worked for days to find odds and ends of your life, and someone steals it!

As the sun set on Breezy Point, November 13th 2012, several of us knew we'd be back, with whatever they needed, whenever they needed it.

Thank you for all that you've done, and all that we have left to do.

Cynthia Hill, the Breezy Point Project

Steve send me a link to an article about his friend and travel agent Cynthia Hill.  Cynthia knows some firefighters who live in Breezy Point and work in Manhattan.  She organized a drive for items that were sorely needed in the recovery efforts, got the Stop-and-Shop supermarket chain to donate trucks, and got locals firefighters to help with loading efforts in Wayland MA.

Of all the available AntennaSys resources, the most important for this mission were three: a credit card, an enclosed trailer (which we use to transport equipment and supplies for the courses we teach) and cheap labor.  These were immediately pressed into service.  With a shopping list in hand, and additional text messages relayed to me from Cynthia via Steve, my daughter Samantha and I headed to Cyr Lumber to load up.

As keeper of the list, Samantha made sure we got the highest priority items.  We were time-limited and needed to be on the road at 2pm in order to make the drop.

Cynthia not only got Stop-and-Shop to donate trucks, but these trucks were staged in the brand-new parking lot of a supermarket that was not yet open.  

What an amazing operation.  We were unloaded in four minutes and watched one of TWO 40-foot trailers hit it's limit.

Best of luck Breezy Point.  Thank you Cynthia, Stop-and-Shop, and the Firefighters.

Now, back to antennas...

Thanks for your patience as we clean up after Sandy.

S

There is hope. A crew was working on the lines that were downed by a large tree. Four poles were taken out. I am checking gmail, and I hope our mail server is back on the net by Friday.

My thoughts are with folks in NYC and surrounds, who were really pounded by Superstorm Sandy.

Be safe. Persist.

-S

Brought to you by..... antennas.  Turning RF signals into electrical currents for over 100 years.

Good Work Space-X!

U.S. Military Special Forces Buy Unique Satellite Receive Suite From Nashua-Based Windmill International, Inc.

Windmill International, Inc. announced that it has received a $9 million order for their KA-10 Suitcase Portable Receive Suite (SPRS) for Central Command Special Forces in Afghanistan.  The order included KA-10s, training, and product support. Windmill's KA-10 SPRS is a highly-portable, rugged satellite receiver system developed to support Special Operations forces deployed overseas.  The battle-ready KA-10 conveniently brings crucial command center information and data to the in-field warfighter, substantially improving mission success probabilities and saving lives. [...more]

In September of 2004, Mr. David Martin (Windmill International, Inc.) and I, along with our AFRL sponsor Mr. John Turtle briefed the Special Operations Command on the results of our SBIR Phase I and Phase II program.  The briefing was entitled "AFRL SBIR contract to develop lightweight GBS Rx antenna for Special Forces".  The press release above is the culmination of that briefing and the result of hard work by a fantastic engineering team that simply did not understand that it couldn't be done.

Dave Martin (R) and myself (L) at Wahiawa, HI demonstrating the "Iron Maiden" in July 2004

In the picture above, our prototype weighed 65 lbs., but replaced about 400 lbs. of equipment, and ran on batteries.  The then-current system is shown in the background; it is a 1-meter dish antenna.  The "Iron Maiden" was the precursor of the new KA-10 system which weighs about 40 lbs. 

The working prototype KA-10, with Dave and I on our way to a demo in Washington DC, December 2005

The original goal of the system was to be sized for airline carry-on.  It struck us that we had achieved our goal when we were on a commuter jet bound for DC from Manchester NH.  (Photo by Dave Martin)

Upon arriving at Dulles, we were reminded by the Arrivals Board that while the hardware may be working perfectly, there were things that could still go wrong.  One challenge was that it was FREEZING in DC when we got there, and had to go to the mall to buy thermal underwear for the demo.  We demonstrated the unit on Pearl Harbor Day, December 7th, 2006.

The system worked perfectly, though the demo gremlins were quite active.  We had overcome magnetic anomolies, loose hardware, and a temperature-related sensor failure.  All these things were taken back to the engineering team as lessons learned and made the ultimate product better.  And, yes, we blamed some problems on software... unfairly.  Sorry, Dan.

There are many, many people to thank for having worked on this project, and I have not asked any of them permission to use their names.  But to them I say THANK YOU!!  It's been a wild ride.

At MILCOM 2006

(U.S. Patent 7,889,144 and other U.S. and International Patents both issued and pending.)

And playing the game is not optional.

-with apologies to C. P. Snow

Breaking the laws of physics is a popular pastime. Who would not want to get a thousand miles per gallon, lose weight by taking a pill, or receive a fortune in cash from a Nigerian prince by email? But, most of us understand it just ain't going to happen. And so it is with antennas. Previously, I wrote about the tradeoffs associated with antennas. The most contentious corner of our tradeoff triangle seems to be size; it's the easiest to measure, and the one in most visible conflict with other aspects of wireless product design.

You want your antenna small, admit it.

Small antennas have been around a long time. Remember pagers? They most often operated in the VHF band, where wavelengths were on the order of two meters. Yet, they were tiny (although the volume of cell phones is approaching what later model pagers were) and the antennas they contained were even tinier. The facts that enabled their good performance were: narrow frequency range and receive-only operation. You can have small size if you give up bandwidth and efficiency. No problem. For many years, AM radios operated from 510-1800 KHz (with wavelengths in the hundreds of meters) using a ferrite loopstick at the core of their antenna; narrow bandwidth, low efficiency, and completely successful.

But, these days who wants to give up bandwidth? If size is the easiest thing to measure, then impedance bandwidth is a close second. An RF network analyzer can measure impedance bandwidth in a few milliseconds, and generate a curve which can be put in a data sheet, or used to compare to an existing data sheet. So, let's make a small antenna with wide bandwidth!! If we're lucky, nobody will ask about the efficiency (which is pretty hard to measure, but easy to experience).

And so, some companies manufacture Antennuators. These are a cross between antennas and attenuators. Between good and evil. Between protein and carbohydrates. Between Apple and Microsoft. Let's radiate some energy and burn some energy as heat. That way, it's kind of usable, and the measured impedance bandwidth is glorious!

There are several ways to build an Antennuator. The easiest method is to build it with lossy materials in the parts that carry RF current. One example of such a material is stainless steel. Stainless steel is a rather poor conductor, but its nice to look at and resists corrosion. There are many whip antenna made from stainless steel, and often the environmental considerations outweigh the loss from the material selection. And in certain antenna types, which are inherently high impedance (such as the Kraus Helical) the difference in material losses will be insubstantial. But, when antennas are made physically small the currents can get rather high, and this is where lossy materials will rear their ugly head.

A few years ago I was working for a company that manufactured various specialized receivers and transmitters operating in the VHF, UHF and low-microwave range. I was the in-house antenna engineer as well as a product designer. A good friend of mine, John D., came to my office with a question. He ran the test department which had the responsibility of tuning and testing all the equipment before shipment. A group of "tactical repeaters" were being tested, and one was on his bench transmitting a few watts of RF at VHF into a six- or eight-inch "rubber duck" antenna (a helically wound short monopole).

"Spence, should the antennas get warm?"

I turned and looked at him incredulously. After careful consideration I answered with a incisive question of my own, "HUH?!!?"

"After about five minutes the antenna is warm, and I don't remember this happening before. Is it normal?" John asked.

"Hell, no!" was my measured response which began a careful investigation into this Antennuator.

I verified that, indeed, the antenna was warming up substantially, and that it was not some other portion of the system making heat and warming up the antenna. After some digging, John and I determined that there was a recent vendor change from vendor "C" to vendor "A". I grabbed some examples of the parts from each vendor and started cutting them open (this is a recurring theme, as you will see, Dear Reader). The helical conductor from vendor "C" was copper-colored, and that from vendor "A" was stainless-steel colored. Hmmmm.

Then I took scraps of the plastic that encased each antenna and carefully tested the dielectric loss using an UHF RF Thermal Conversion Exposure Cavity. Yep. . . a microwave oven. The difference in thermal dissapation between the two plastics was very significant: after about 15-20 seconds of exposure (with a cup of water at the opposite corner of the microwave for loading) the plastic from vendor "A" got hot whereas that from vendor "C" was not noticably warmer -- lossy dielectric confirmed. (While this test was conducted at about 2450 MHz, it is still indicative of losses at VHF.)

The Antennuator from vendor "A" looked great on the RF network analyzer, and even better in the purchasing department's scorecard. But, it was burning precious (battery powered) RF in the process. I immediately wrote an ECO (Engineering Change Order) eliminating vendor "A" as a supplier, and specifically naming vendor "C" as the supplier for this particular part. Problem solved. Purchasing had been credited for saving money on cheaper antennas, and Engineering looks evil throwing out inventory. The Earth continued turning on its axis.

More recently, one of my clients brought me a product from a Serious Defense Contractor, which was labelled "Antenna, Broadband, 50-2000 MHz". It was about twelve inches long, about 5/8-inch in diameter, with a BNC male connector on one end. It was flexible, black, and no doubt expensive. Since my client was taking a training class, I immediately used it as an example of an Antennuator. I started a discussion with the class as to how a twelve-inch long antenna can be rated for operation from 50-2000 MHz. After a healthy amount of discussion, one of the students put the antenna on an RF network analyzer and swept it from 50-2000 MHz, measuring the input impedance.

"It looks good to me!" he said, showing a respectable "knot" in the middle of the Smith Chart, indicating a VSWR of less than about 2:1 (ref. 50-ohms) over the range.

I said, "You'd think so, but remember the engineering rule: if you can't fix it, at least you can break it!". I extended the low end of the measurement down to 2 MHz. And do you know what we saw? It still had a VSWR of about 2:1. . . . but, it shouldn't have. It SHOULD have looked lousy at 2 MHz. Now think, what has a VSWR of 2:1 at 2-, 50- and 2000-MHz? That's right -- a RESISTOR!

I made a bold (and risky) statement to the class: "There's a 100-ohm resistor in parallel with the connector.", I confidently proclaimed, hoping like hell nobody would call me on it. Well, I was with a group that did not see any impediment to cutting open the antenna and finding out Right Now. And so, they did.

I was wrong. There were two, 200-ohm resistors (each rated 3-watts) in parallel across the connector. As I see it, when RF current flows in a conductor the only thing it can make is radiation, but when RF current flows in a resistor the only thing it can make is heat. So, the ONLY possible reasons those resistors were there were to make the transmitter happy over that frequecy range (no spurious oscillation, no VSWR alarms), to make the datasheet look magnificent (and meet procurement requirements), or to prevent the buildup of ice. Unfortunately, my clients are professional communicators and in need of their equipment actually... you know... communicating, and they were already acutely aware of the inefficiency of this product. Putting "50-2000 MHz" on the body of an antenna does not make it so. Notice the efficiency was not stated on the same placard. Pity.

Once I designed an antenna for a small surveillance product that had a resistor in it. The product was battery operated, and had a very high efficiency transmitter. Sometimes, however, if the antenna came too close to a conductor, it presented the transmitter with a very low impedance that caused a spurious oscillation. This was Very Bad in the intended application. I ended up using a small series resistor in the feed loop of the electrically small loop antenna. The cost of this resistor was a fraction of a dB of transmitted signal in normal operation, but it prevented the spurious oscillation completely and the associated loss of signal. This was a carefully weighed decision, it solved the problem, and the efficiency cost was calculated and acceptable. The problem could have been solved further upstream in the power amplifier, and there would have been an efficiency cost there, too.

Resistors turn current into heat. That's what they're supposed to do, and thank goodness they do it so well. But, when you find 'em in antennas, it's worth asking why they're there.

Sometimes, it's useful to burn undesired energy of the wrong polarization as in a Terminated Bifilar Antenna or a Log Spiral Antenna, for example. In that case, polarization purity (axial ratio) is more valuable than efficiency. That is an engineering decision, and a good one.

Sometimes, it's critical to keep the transmitter happy and invest in a bit of heat to do so.

Sometimes, it's to make the datasheet look miraculous and score a big order from the government.

Perhaps someone should ask the professional communicators if the solution to their very real problems is an Antennuator. I think not.

You can have it:

    Fast
    Accurate
    Cheap

Pick any two.

Every professional pursuit has its tradeoffs which must be managed.  In fact, I believe that it is the principal function of the engineer to manage tradeoffs.  We want airplanes to be strong, but light and affordable.  We want our favorite restaurant to be inexpensive, tasty and prompt.  We want our politicians to be honest, responsive and effective (OK... it's just theoretical). These competing desires are what we call the Tradeoff Triangle.  Sometimes the number of parameters we need to balance exceeds three, but for the purposes of our discussion today, the number shall be three... no more, no less.  Three shall be the number of thine tradeoffs, and the number of the tradeoffs shall be three. Four shalt thou not consider, neither ponder thou two, excepting that thou then proceed to three. Five is right out.

But, I digress.

Let's explore what the job of an antenna is, and where its tradeoffs can be found and thence managed.  And we are going to assume that antennas are reciprocal.  That means they can make radiation from RF current (transmitting), and they can make RF current from radiation (receiving).  In any wireless device, there is a receiver section, a transmitter section or both (transceiver).  These functional blocks are designed by a clever and talented RF guy, and generally interface to the antenna via a transmission line of a certain characteristic impedance; the most familiar values for this impedance are 50- and 75-ohms.  (The reason for the existance of these two values is a good subject for a future blog entry.  Anyone know the history of these choices?)

Usually, I hate it when someone tells me the punchline before I hear the joke.  Sorry, but here it is: Your antenna can be wideband, small or efficient.  BANDWIDTH, SIZE, EFFICIENCY.  Pick any two.  It is a sure sign of Antenna Snake Oil when you see tiny, wideband antennas boasting ultra-high efficiency.  Run the other way.  OK, let's take a closer look...

Antennas operate over limited bands of frequencies.  Sometimes these bands are smaller than we wish they were.  A useful way to think about bandwidths is called "fractional bandwidth" (FBW); for our purposes we'll define fractional bandwidth as the high frequency divided by the low frequency.

For example, modern cell phones generally require antennas that operate from 806 to 915 MHz (FBW=1.14 or 14%) AND 1710 to 1990 MHz (FBW=1.17 or 17%).  This covers all the GSM bands as well as the PCS bands.  Another familiar band is the 2.4 GHz ISM band which is where WiFi lives; this band is 2.4 to 2.5 GHz (FBW=1.04 or 4%).  Yet another example is the 900 MHz ISM band which is often used for wireless phones and other household and office devices; this band is 902 to 928 MHz (FBW=1.03 or 3%).  And finally, we are all familiar with GPS which needs about 10 MHz of bandwidth centered around 1575 MHz (FBW=1.006 or less than 1%).

So, antennas for each of these applications need to operate over the entirety of these bands.  This property, which is the first of our three tradeoffs is loosely called BANDWIDTH.  In the four examples above, note that the fractional bandwidth is representative of how "hard" it is to meet this requirement in light of our (soon to be illuminated) other tradeoffs.  GPS seems easy, and "Quad Band GSM" seems hard.  And so they are.  

Now, using the term "bandwidth" without any further qualification is Engineering Blasphemy (see also my rants about the use of "dB" without a reference).  The bandwidth of an antenna is completely dependent upon what is relevant to the application.  For cellphone applications, it may be the "efficiency bandwidth" or that bandwidth over which the total radiated power (TRP) or the total isotropic sensitivity (TIS) is north of a required value.  For GPS we may be bandwidth-limited by the axial ratio, or the quality of the circular polarization (RHCP in the case of GPS).

Frequently, the bandwidth of concern is the impedance bandwidth, which is the bandwidth over which the antenna's impedance remains within a certain "distance" (on the Smith Chart) of the ideal impedance.  Often this is expressed as Return Loss (10 dB is the usual minimum value), or VSWR (Voltage Standing Wave Ratio) where 2:1 is the usual limit.  If someone uses the term "antenna bandwidth" without explicity saying which bandwidth they are referring to, it is probably the impedance bandwith.  And thereafter they shall be scolded.

The second tradeoff in our triangle is SIZE.  There's different ways to think about  size.  You care about physical size when you are trying to stuff ten pounds of stuff in a five pound bag: you want your consumer product to be as small as possible and the industrial designer has graciously given you a volume which would not host most DNA molecules.  The antenna designer is thinking in terms of wavelengths.  As the antenna volume starts becoming a smaller and smaller fraction of a wavelength, the impedance bandwidth starts shrinking, and the ability to remain efficient with real-world materials starts disappearing.  

In December 1948, Lan Jen Chu published the paper "Physical Limitations of Omni-Directional Antennas", in which he derived a theoretical formula of the bandwidth of an electrically-small antenna.  In the interest of circumnavigating a soporific vortex, the conclusion is thus: the smaller the antenna, the narrower the bandwidth.  So there.

EFFICIENCY is the measure of how much of your RF power is going to be radiated, and how much is going to be turned into heat.  Assuming your goal is not de-icing, heat is an undesireable byproduct.  With real-world materials, especially as we shrink antennas, this becomes a significant concern.  A side-effect of shrinking the antenna is causing the antenna's RF currents to become large enough to make the radiation happen.  These high currents make the material losses which were previously ignorable a very real concern.  I have designed electrically-small loop antennas which have a radiation resistance (the good "resistance") measured in milliohms.  Suddenly the fact that the conductor is copper as opposed to aluminum becomes really important.  The dielectric materials used in trimmer and fixed capacitors for resonating such antennas become critical.

While it is pretty clear that losses in conductors and dielectrics are undesireable from an efficiency standpoint, there lurks in the shadows a side effect as enticing as it is detrimental.  These efficiency-robbing losses make the impedance bandwidth appear larger.  In fact, the higher the losses the wider the impedance bandwidth until the limit where ALL the energy is dissipated in losses and the bandwidth seems "infinite".  The ultimate example is a 50-ohm terminator: a perfect match over a huge bandwidth... and zero radiation.  The Dummy-Load Antenna.  The lesson is clear: When presented with an antenna with unexpectedly large bandwidth for its size, ask about the efficiency.  Oftentimes, this line of questioning is met with a stunned silence at best, or a complete change of topic at worst.  There is a tiny fraction of antenna companies operating today whose business plans depend upon your failing to inquire about efficiency.  I'll say it again: About the Efficiency -  Ask!

The product designer, antenna designer, industrial designer and marketing professional together must all cooperatively grapple with the antenna tradeoff triangle: BANDWIDTH, SIZE, EFFICIENCY.

Like it or not... Pick two.