[CQ-Contest] Implementing a Dynamic error free RBN-Skimmer network

Ron Notarius W3WN wn3vaw at verizon.net
Wed Jul 17 17:59:48 EDT 2013


And this is bad because... ?

-----Original Message-----
From: CQ-Contest [mailto:cq-contest-bounces at contesting.com] On Behalf Of
Martin , LU5DX
Sent: Wednesday, July 17, 2013 5:32 PM
To: CQ-Contest
Subject: Re: [CQ-Contest] Implementing a Dynamic error free RBN-Skimmer
network

I guess no stations can call CQ on alternate frequencies on the same band
now (MS/M2/MM)...

Vy 73.

Martin, LU5DX


On Wed, Jul 17, 2013 at 3:53 PM, Igor Sokolov <ua9cdc at gmail.com> wrote:

> Very well done Jose. Thank you much. I have enjoyed reading it.
>
> Couple of thoughts came to my mind.
> There are instances where one station can be heard on several frequencies.
> 1) Stations with parasitic AM modulation can have 3 signals spaced aprox.
> 1.5 kHz
> 2) Second and third harmonic signals.
> 3) Multy/ Multy stations.
>
> How does your algorithm treats these cases?
>
> 73, Igor UA9CDC
>
> ----- Original Message ----- From: "José Nunes CT1BOH" <ct1boh at gmail.com>
> To: <cq-contest at contesting.com>
> Sent: Tuesday, July 16, 2013 4:23 AM
> Subject: [CQ-Contest] Implementing a Dynamic error free RBN-Skimmer
network
>
>
> The purpose of this post is to present a way to implement a dynamic error
> free Skimmer-RBN/Packet network that automatically:
>
> 1. Flags and eliminates “Busted Spots” from the network
> 2. Flags  and eliminates “wrong frequency” spots from the network
> 3. Prevents inaccurate Skimmer-Spotters from feeding incorrect spots to
the
> network
> 4. Eventually allow the Skimmer-RBN users to customize reception of spots
> according to the quality flag and several parameters of the algorithm
>
> In my various CQWW CW operations since 1989
>
http://www.qsl.net/ct1boh/**operations.htm<http://www.qsl.net/ct1boh/operati
ons.htm>I’ve only enjoyed
> Skimmer-RBN/Packet networks from the pile-up end side as PY0F, P40E, CR3E,
> etc.
> Skimmer-RBN and packet network has been a blessing for the DX operator as
a
> constant pile-up generator and a reason for the never ending increase in
> total QSO number throughout the years.
>
> Recently, building the idea of operating Assisted on CW from a DX location
> for the first time, I begun to study how to correctly use
> Skimmer-RBN/Packet networks. Operating Assisted in minor Contests from
> home, I discovered several problems that made the use of callsign and
> frequency information from a RBN feed band map not 100% reliable:
>
> - Busted spots
> - Non-existent spots on a particular frequency
> - Small frequency shifting spots and
> - “Unstable” band map with callsigns alternating, popping-in and
> popping-out
>
> Wanting to use Assistance and not being able to completely trust the
> information is a strange concept to me. If I use Assistance I would expect
> not to waste time in my mind processing if the call in the band map is
good
> or bad.
>
> Solving the problems requires a system that is able to automatically
assess
> the spot before send it to the network and “learns” from itself. The
> solution is a dynamic error free RBN-Skimmer algorithm.
>
> Studding RBN data that can be downloaded here
>
http://www.reversebeacon.net/**raw_data/<http://www.reversebeacon.net/raw_da
ta/>I came to a solution. The algorithm
> I propose has a simplicity beauty and works extraordinary well. For every
> new spot that is provided to the Reverse Beacon Network by a Skimmer
> Spotter or by a packet network by a human, the system will automatically
> generate the following “Quality Tag” for each spot:
>
> Good Spot
> Good Call, New Frequency Spot?
> Busted Spot
> ? Spot
>
> In short, the algorithm can be described as follows:
>
> Any new spot will be tagged as a “Good Spot” if looking back 25 minutes
> there are two more Spots with the same call as the new spot, in the
> approximate same frequency (+/- 0.3 Khz)
>
> Any new spot will be tagged as a “Good Call, New Frequency Spot?” if
> looking back 25 minutes there is a Spot that was already tagged as “Good
> Spot”, with the same call as the new spot, but the new spot is in an
> adjacent frequency (less or equal than -0.4 Khz and greater or equal than
> +0.4 Khz)
>
> Any new spot will be tagged as “Busted Spot” if looking back 25 minutes
> there are at least three already tagged “Good Spot” with a similar call,
in
> the approximate same frequency of the new spot (+/- 0.1 Khz). The similar
> call is a call that can be transformed into the new spot call by character
> insertion, deletion or substitution.
>
> Any Spot that is not a “Good Spot”, a “Good Call, New Frequency Spot?” or
a
> “Busted Spot” is an undetermined spot “?Spot”.
>
> Let’s have a closer look at it, with examples from RBN spots from CQWW CW
> 2012:
>
> “Good call” quality flag
>
> #1       call1    freq1   time1   #Spotter      Quality tag
> 711     CR3E   7045    4           #G4HYG       ?Spot
> 860     CR3E   7045    5           #WB8BIL      ?Spot
> 918     CR3E   7045    5           #WB2LSI      Good Spot
> 3077   CR3E   7045    20         #G4HYG       Good Spot
> 3254   CR3E   7045    21         #S52AW       Good Spot
> 3336   CR3E   7045    22         #KB9AMG    Good Spot
> 3892   CR3E   7045    25         #DK9IP         Good Spot
> 

> CR3E started the contest (CQWW CW 2012) on 7045. The first two spots get
> the quality flag “?Spot”, but by the third spot of WB2LSI skimmer CR3E is
> flagged as a “good call” and all subsequent spots on 7045 will get the
> “Good Spot” quality flag.
> After a lot of testing I can say the system should operate with a
bandwidth
> filter of +/- 0.3 KHz. All spots that do not fall within this +/- 0.3 KHz
> filter will not get the “Good Spot” quality tag.
>
>
> “Good Call, New Frequency Spot?”
>
> #1          call1    freq1      time1   #Spotter      Quality tag
> 

> 33721   CR3E   7045       220       #F5MUX       Good Spot
> 34154   CR3E   7041.3    223       #KA9SWE     Good Call, new freq?
> 34460   CR3E   7045       225      #RU9CZD      Good Spot
> 

> 40711   CR3E   7044.9    261       #KQ8M         Good Spot
> 40740   CR3E   7041.3    261       #KA9SWE    Good Call, new freq?
> 41213   CR3E   7045.1    264       #K3LR          Good Spot
> 

> CR3E continues to be on 7045. All of a sudden #KA9SWE skimmer spots CR3E
on
> 7041.3. The systems detects a frequency difference and flags it as a “Good
> call, new frequency?”.  Is it really a QSY to a new frequency by CR3E? If
> yes, then, shortly after two more spots the system will change the flag to
> “Good spot”. It is not the case in this example because skimmer #RU9CZD
> confirms there was no QSY. Later on we see that #KA9SWE sends another spot
> on 7041.3.Obviously #KA9SWE skimmer needs frequency calibration.
> After a lot of testing I can say the system should operate with a
bandwidth
> filter of greater than +/- 0.3 Khz. All spots that do not fall within this
> +/- 0.3 KHz filter will not get the “Good Spot” quality tag, and this
> should be the accuracy threshold.
>
>
> “Busted Spot”
>
> #1          call1       freq1     time1   #Spotter      Quality tag
> 31159   CR3E      7045      204       #S52AW      Good Call
> 31172   KR3E      7045      204       #K9QC          Busted
> 31205   CR3E      7045      205       #G4HYG       Good Call
> 

> CR3E continues to be on 7045. All of a sudden #K9QC skimmer sends a KR3E
> spot. The system detects that KR3E is a similar call of CR3E on the same
> frequency of a Good Spot and it will flag this spot as a Busted spot. The
> system uses Levenshtein distance to calculate a similar call (
>
http://en.wikipedia.org/wiki/**Levenshtein_distance<http://en.wikipedia.org/
wiki/Levenshtein_distance>).
>  Depending on the
> length of the callsign it will look for calls that are x-off letters away.
> After a lot of testing I can say the system should operate with a
bandwidth
> filter of +/- 0.1 Khz. A Busted Spot comes from a good spot, and usually
> from Skimmer that has already spotted the call, therefore a threshold of
> 0.1 is what works best.
>
>
> “?Spot”
>
> All “?Spot” are spots that cannot be determined as “Good Spot” or as “Good
> Call, New Frequency Spot?” or as “Busted Spot”.  Some are good spots – The
> first and the second spot on a new frequency when a run starts. But the
> majority is “spots” send by skimmers, of stations calling RUN stations.
> These spots should never be sent out to the network by skimmer. They are
> false positive running stations.
>
>
> How does this proposed system works?
> I can say it works extraordinary well!
>
> I tested all 40 meter spots from CQWW CW 2012 – almost a million sots:
>
> Quality flag                               Spots        % of spots
> ?                                            46.593              4.69%
> Busted                                   20.734               2.09%
> Good Call                             855.227              86.08%
> Good Call, new freq?               70.994               7.15%
> Grand Total                          993.548            100.00%
>
> After running my algorithm I also went back to validate both “? Spots” and
> “Good call, new freq?” spots. If I have the following spots:
> 711     CR3E   7045    4           #G4HYG       ?Spot
> 860     CR3E   7045    5           #WB8BIL      ?Spot
> 918     CR3E   7045    5           #WB2LSI      Good Spot
> It is easy to determine after running the algorithm that spot #711 and
> spot#918 are “Good Spots” from spot 918. This cannot be done with a real
> time system, because once a quality tag is given to a spot it is given.
>
> Of the 46.593 spots with “?Spot” quality flag:
>     20768 are good calls (these are all the first and second spot of a run
> that just started)
>     25825 spots are indeed “? Spots” (mostly stations calling on pile-ups)
>
> Of the 70.994 spots with “Good Call, New Freq?” quality flag:
>     24.502 are good call (these are all the first and second spots of a
> run that just started in a new frequency)
>     46.492 spots are indeed “Good Call” that are sent to the network with
> a wrong frequency by an uncalibrated skimmer.
>
> My algorithm also allows the RBN to detect uncalibrated skimmer spotters.
>
> Looking at the list of skimmers it is easy to build a list based on the %
> of “Good call, New freq?” quality flag. Let’s take a look at the top ten
> Skimmer spotters according to spots sent to the RBN:
>
> Skimmer     Spots          % of “Good Call, New Freq?”
> #K3MM     45.726         3.1%
> #GW8IZR  29.984         8.7%
> #S52AW    29.214        5.2%
> #DL8LAS   26.906         3.7%
> #DR1A      25.831         3.1%
> #RU9CZD 24.301          6.4%
> #HA6PX     23.317      38.6%
> #OL5Q      23.006         4.4%
> #W3LPL   21.889          2.0%
> #KQ8M    21.833          7.1%
>
> We can see that a calibrated skimmer should not have more than 3% of “Good
> Call, New frequency?” spots, because that is the dynamic of people
changing
> frequency in the contest. Numbers greater than that show uncalibrated
> skimmers, such is the case of #GW8IZR, #HA6PX, or #KQ8M.
>
>
> To finalize several considerations:
>
> 1 RBN (Reverse Beacon Network) is a fantastic instrument for contesters
and
> DXers.
> 2 We have the instruments to turn the current RBN network into a dynamic
> error free system
> 3 The system should allow the user to decide to filter out “Busted” spots,
> “Good call, New Freq?” spots and “? Spots”. By giving a quality flag it
> would be up to the user to use the quality flags to filter out spots
> 4 The system should warn uncalibrated skimmers
>
> If you want to play with the data and with the algorithm you can:
> The algorithm and several graphs that explain how well the system works is
> available to download here
> http://www.qsl.net/c/ct1boh//**dl/ <http://www.qsl.net/c/ct1boh//dl/>
> Please note that the excel file is ~90MB
>
> In sheet 1 there are 993.548 spots from CQWW CW 2012 on 40 meters
> In sheet 2 there is the results of the algorithm. This would be the output
> of the system with real time adding a quality flag to each spot (if you do
> Alt-Q you will activate the macro. it takes 1892 seconds to flag all
> 993.548 spots on my PC. Or on average 0.0019 seconds to flaf every
incoming
> spot.
> In sheet 3 there is a pivot table to manipulate data from sheet 2
> In sheet 4 there is a list and graph that show the performance of skimmers
> as far as frequency calibration is concerned
> In sheet 5 there is a list and a graph of calls and the % of Busted of
each
> call according to number of spots
> In sheet 6 there is the algorithm code (please note that I’m not a
> programmer. I just learned VBA to do this)
>
>
> --
> José Nunes
> CONTEST CT1BOH - http://www.qsl.net/ct1boh
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