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Additions to User Guide.
git-svn-id: svn+ssh://svn.code.sf.net/p/wsjt/wsjt/branches/wsjtx@7219 ab8295b8-cf94-4d9e-aec4-7959e3be5d79
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@ -51,3 +51,38 @@ and your own preferences.
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Smoothing the displayed spectrum over more than one bin can enhance
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Smoothing the displayed spectrum over more than one bin can enhance
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your ability to detect weak EME signals with Doppler spread more than
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your ability to detect weak EME signals with Doppler spread more than
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a few Hz.
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a few Hz.
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[[CONTROLS_FAST]]
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=== Fast Graph
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Three sliders at the bottom of the Fast Graph window can be used to
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optimize gain and zero-offset of the displayed information. Hover the
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mouse over a control to display a tip reminding you of its function.
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Clicking the *Auto Level* button will produce reasonable settings
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as a starting point. The waterfall palette used on this graph is
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the same as the one selected on the Wide Graph.
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image::fast-graph-controls.png[align="center",alt="Fast Graph Controls"]
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[[CONTROLS_ECHO]]
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=== Echo Graph
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Controls at the bottom of the Echo Graph
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- *Bins/Pixel* controls the displayed frequency resolution. Set this
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value to 1 for the highest possible resolution, or to higher numbers
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to compress the spectral display.
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- *Gain* and *Zero* sliders control scaling and offset of plotted
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spectra.
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- *Smooth* values greater than 0 apply running averages to the plotted
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spectra.
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- Label *N* shows the number of echo pulses averaged.
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- Click the *Colors* button to cycle through 6 possible choices of
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color and line width for the plots.
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image::echo-graph-controls.png[align="center",alt="EchoGraph Controls"]
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BIN
doc/user_guide/en/images/echo-graph-controls.png
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doc/user_guide/en/images/echo-graph-controls.png
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After Width: | Height: | Size: 2.1 KiB |
BIN
doc/user_guide/en/images/fast-graph-controls.png
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BIN
doc/user_guide/en/images/fast-graph-controls.png
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Binary file not shown.
After Width: | Height: | Size: 2.1 KiB |
@ -1,106 +1,110 @@
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[[JT65PRO]]
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[[PROTOCOL_OVERVIEW]]
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=== JT65
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=== Overview
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JT65 was designed for making minimal QSOs via EME ("`moon-bounce`") on
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All QSO modes except ISCAT benefit from the use of structured
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the VHF and UHF bands. A detailed description of the protocol and its
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messages. Each such message consists of two 28-bit fields for
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implementation in program _WSJT_ was published in {jt65protocol} for
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callsigns and a 15-bit field for a grid locator, report,
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September-October, 2005. Briefly stated, JT65 uses 60 s T/R sequences
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acknowledgment, or a "`73`" sign-off indicator. Alternatively, a
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and carefully structured messages. Standard messages are compressed so
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72^nd^ bit flags a message containing arbitrary alphanumeric text, up
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that two callsigns and a grid locator can be transmitted in just 71
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to 13 characters. Special formats allow other information such as
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information bits. A 72^nd^ bit serves as a flag to indicate that a
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add-on callsign prefixes (e.g., ZA/K1ABC) or suffixes (e.g., K1ABC/4)
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message consists of arbitrary text (up to 13 characters) instead of
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to be encoded. The basic aim is to compress the most common messages
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callsigns and a grid locator. Special formats allow other information
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used for minimally valid QSOs into a fixed 72-bit length. To be
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such as add-on callsign prefixes (e.g., ZA/K1ABC) or numerical signal
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useful, this kind of lossless message compression requires use of a
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reports (in dB) to be substituted for the grid locator. The basic aim
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strong forward error correcting (FEC) code. Different FEC codes are
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is to compress the most common messages used for minimally valid QSOs
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used for each mode. These modes require good synchronization of time
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into a minimum fixed number of bits. After compression, a Reed Solomon
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and frequency between transmitting and receiving stations. As an aid
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(63,12) error-control code converts 72-bit user messages into
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to the decoders, each protocol includes a "`synch vector`" of known
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sequences of 63 six-bit channel symbols.
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symbols along with the information-carrying symbols. Generated
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waveforms for all of the _WSJT-X_ modes have continuous phase and
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JT65 requires tight synchronization of time and frequency between
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a constant envelope.
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transmitting and receiving stations. Each transmission is divided into
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126 contiguous tone intervals or "`symbols`" of length 4096/11025 =
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0.372 s. Within each interval the waveform is a constant-amplitude
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sinusoid at one of 65 pre-defined frequencies. Frequency steps between
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intervals are accomplished in a phase-continuous manner. Half of the
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channel symbols are devoted to a pseudo-random synchronizing vector
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interleaved with the encoded information symbols. The sync vector
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allows calibration of time and frequency offsets between transmitter
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and receiver. A transmission nominally begins at t = 1 s after the
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start of a UTC minute and finishes at t = 47.8 seconds. The
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synchronizing tone is at 11025 × 472/4096 = 1270.46 Hz, and is
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normally sent in each interval having a “1” in the following
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pseudo-random sequence:
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100110001111110101000101100100011100111101101111000110101011001
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101010100100000011000000011010010110101010011001001000011111111
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Encoded user information is transmitted during the 63 intervals not
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used for the sync tone. Each channel symbol generates a tone at
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frequency 11025 × 472/4096 + 11025/4096 × (N+2) × m, where N is the
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value of the six-bit symbol, 0 ≤ N ≤ 63, and m is 1, 2, or 4 for JT65
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sub-modes A, B, or C. Sub-mode JT65A is always used at HF.
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For EME (but, conventionally, not on the HF bands) the signal report
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OOO is sometimes used instead of numerical signal reports. It is
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conveyed by reversing sync and data positions in the transmitted
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sequence. Shorthand messages for RO, RRR, and 73 dispense with the
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sync vector entirely and use time intervals of 16384/11025 = 1.486 s
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for pairs of alternating tones. The lower frequency is always 1270.46
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Hz, the same as that of the sync tone, and the frequency separation is
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110250/4096 = 26.92 Hz multiplied by n × m, with n = 2, 3, 4 for the
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messages RO, RRR, and 73.
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[[JT4PRO]]
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[[JT4PRO]]
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=== JT4
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=== JT4
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JT4 uses 72-bit structured messages nearly identical to those in
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FEC in JT4 uses a strong convolutional code with constraint length
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JT65. Error control coding (ECC) uses a strong convolutional code with
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K=32, rate r=1/2, and a zero tail. This choice leads to an encoded
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constraint length K=32, rate r=1/2, and a zero tail, leading to an
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message length of (72+31) x 2 = 206 information-carrying bits.
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encoded message length of (72+31) x 2 = 206 information-carrying
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Modulation is 4-tone frequency-shift keying (4-FSK) at 11025 / 2520 =
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bits. Modulation is 4-tone frequency-shift keying at 11025 / 2520 =
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4.375 baud. Each symbol carries one information bit (the most
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4.375 baud. Each symbol carries one information bit (the most
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significant bit) and ony synchronizing bit (the least signicifant
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significant bit) and one synchronizing bit. The pseudo-random sync
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bit). The pseudo-random sync vector is the following sequence:
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vector is the following sequence:
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000011000110110010100000001100000000000010110110101111101000
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000011000110110010100000001100000000000010110110101111101000
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100100111110001010001111011001000110101010101111101010110101
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100100111110001010001111011001000110101010101111101010110101
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011100101101111000011011000111011101110010001101100100011111
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011100101101111000011011000111011101110010001101100100011111
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10011000011000101101111010
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10011000011000101101111010
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The two 32-bit polynomials used for convolutional encoding have
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hexadecimal values f2d05351 and e4613c47.
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[[JT9PRO]]
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[[JT9PRO]]
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=== JT9
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=== JT9
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JT9 is designed for making minimally valid QSOs at LF, MF, and HF. It
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FEC in JT9 uses the same strong convolutional code aa JT4: constraint
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uses 72-bit structured messages nearly identical (at the user level)
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length K=32, rate r=1/2, and a zero tail, leading to an encoded
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to those in JT65. Error control coding (ECC) uses a strong
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message length of (72+31) × 2 = 206 information-carrying
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convolutional code with constraint length K=32, rate r=1/2, and a zero
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bits. Modulation is nine-tone frequency-shift keying, 9-FSK at
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tail, leading to an encoded message length of (72+31) × 2 = 206
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12000.0/6912 = 1.736 baud. Eight tones are used for data, one for
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information-carrying bits. Modulation is nine-tone frequency-shift
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keying, 9-FSK. Eight tones are used for data, one for
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synchronization. Eight data tones means that three data bits are
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synchronization. Eight data tones means that three data bits are
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conveyed by each transmitted information symbol. Sixteen symbol
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conveyed by each transmitted information symbol. Sixteen symbol
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intervals are devoted to synchronization, so a transmission requires a
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intervals are devoted to synchronization, so a transmission requires a
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total of 206 / 3 + 16 = 85 (rounded up) channel symbols. The sync
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total of 206 / 3 + 16 = 85 (rounded up) channel symbols. The sync
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symbols are those numbered 1, 2, 5, 10, 16, 23, 33, 35, 51, 52, 55,
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symbols are those numbered 1, 2, 5, 10, 16, 23, 33, 35, 51, 52, 55,
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60, 66, 73, 83, and 85 in the transmitted sequence. Each symbol lasts
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60, 66, 73, 83, and 85 in the transmitted sequence. Tone spacing of
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for 6912 sample intervals at 12000 samples per second, or about 0.576
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the 9-FSK modulation for JT9A is equal to the keying rate, 1.736 Hz.
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seconds. Tone spacing of the 9-FSK modulation is 12000/6912 = 1.736
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The total occupied bandwidth is 9 × 1.736 = 15.6 Hz.
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Hz, the inverse of the symbol duration. The total occupied bandwidth
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is 9 × 1.736 = 15.6 Hz.
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[[JT65PRO]]
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=== JT65
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A detailed description of the JT65 protocol was published in
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{jt65protocol} for September-October, 2005. A Reed Solomon (63,12)
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error-control code converts 72-bit user messages into sequences of 63
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six-bit information-carrying symbols. These are interleaved with
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another 63 symbols of synchronizing information according to the
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following pseudo-random sequence:
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100110001111110101000101100100011100111101101111000110101011001
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101010100100000011000000011010010110101010011001001000011111111
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The synchronizing tone is normally sent in each interval having a
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"`1`" in the sequence. Modulation is 65-FSK at 11025/4096 = 2.692
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baud. Frequency spacing between tones is equal to the keying rate for
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JT65A, and 2 and 4 times larger for JT65B and JT65C. For EME QSOs the
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signal report OOO is sometimes used instead of numerical signal
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reports. It is conveyed by reversing sync and data positions in the
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transmitted sequence. Shorthand messages for RO, RRR, and 73 dispense
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with the sync vector entirely and use time intervals of 16384/11025 =
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1.486 s for pairs of alternating tones. The lower frequency is the
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same as that of the sync tone used in long messages, and the frequency
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separation is 110250/4096 = 26.92 Hz multiplied by n for JT65A, with n
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= 2, 3, 4 used to convey the messages RO, RRR, and 73.
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[[QRA64_PROTOCOL]]
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[[QRA64_PROTOCOL]]
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=== QRA64
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=== QRA64
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TBD
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Still to come ...
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[[SLOW_SUMMARY]]
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=== Slow Modes
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[[PROTOCOL_SUMMARY]]
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[[SLOW_TAB]]
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=== Comparison of Slow Modes
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.Parameters of Slow Modes
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[width="90%",cols="3h,^3,^2,^1,^2,^2,^2,^2,^2,^2",frame=topbot,options="header"]
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|===============================================================================
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|Mode |FEC Type |(k,n) | Q| Mod | Baud |BW (Hz)|fSync|TxT (s)|S/N (dB)
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|JT4A |K=32, r=1/2|(206,72)| 2| 4-FSK| 4.375| 17.5 | 0.50| 47.1 | -23
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|JT9A |K=13, r=1/2|(206,72)| 8| 9-FSK| 1.736| 15.6 | 0.19| 49.0 | -27
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|JT65A |RS |(63,12) |64|65-FSK| 2.692| 177.6 | 0.50| 46.8 | -25
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|QRA64A|QRA |(63,12) |64|64-FSK| 1.736| 111.1 | 0.25| 48.4 | -28
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| WSPR |K=32, r=1/2|(162,50)| 2| 4-FSK| 1.465| 5.9 | 0.50|110.6 | -29
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|===============================================================================
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Frequency spacing between tones, total occupied bandwidth, and
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Frequency spacing between tones, total occupied bandwidth, and
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approximate decoding thresholds are given for the various submodes of
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approximate threshold signal-to-noise ratios are given for the various
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JT4, JT9, and JT65 in the following table:
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submodes of JT4, JT9, JT65, and QRA64 in the following table:
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Submode Spacing BW S/N
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Submode Spacing BW S/N
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(Hz) (Hz) dB
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(Hz) (Hz) dB
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@ -125,28 +129,16 @@ JT4, JT9, and JT65 in the following table:
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QRA64D 13.889 888.9
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QRA64D 13.889 888.9
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QRA64E 27.228 1777.8
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QRA64E 27.228 1777.8
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Transmissions in all three modes are essentially the same length, and
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all use 72 bits to carry message information. At user level the modes
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support nearly identical message structures.
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JT4 and JT65 signal reports are constrained to the range –1 to –30
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JT4 and JT65 signal reports are constrained to the range –1 to –30
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dB. This range is more than adequate for EME purposes, but not enough
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dB. This range is more than adequate for EME purposes, but not enough
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for optimum use at HF. S/N values displayed by the JT4 and JT65
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for optimum use at HF. S/N values displayed by the JT4 and JT65
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decoders are clamped at an upper limit –1 dB, and the S/N scale is
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decoders are clamped at an upper limit –1 dB, and the S/N scale
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nonlinear above –10 dB.
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becomes significantly nonlinear above –10 dB. JT9 allows signal
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reports in the range –50 to +49 dB. It manages this by taking over a
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By comparison, JT9 allows for signal reports in the range –50 to +49
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small portion of "`message space`" that would otherwise be used for
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dB. It manages this by taking over a small portion of "`message
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grid locators within 1 degree of the south pole. The S/N scale of the
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space`" that would otherwise be used for grid locators within 1 degree
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present JT9 decoder is reasonably linear (although it's not intended
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of the south pole. The S/N scale of the present JT9 decoder is
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to be a precision measurement tool).
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reasonably linear (although it's not intended to be a precision
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measurement tool).
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JT9 is an order of magnitude better than JT65 in spectral
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efficiency. On a busy HF band, the conventional 2-kHz-wide JT65
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sub-band is often filled with overlapping signals. Ten times as many
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JT9 signals can fit into the same frequency range, without collisions.
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=== ISCAT
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=== ISCAT
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@ -190,74 +182,44 @@ many times as will fit into a Tx sequence.
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=== MSK144
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=== MSK144
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(this section needs work ...)
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Standard MSK144 messages are structured in the same way as those in
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the slow modes, with a 72 bits of user information. Forward error
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MSK144 is intended for meteor-scatter QSOs on the VHF bands. Standard
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correction is implemented by first augmenting the 72 message bits with
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messages are structured in the same way as those in the slow modes,
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an 8-bit CRC calculated from the message bits. The CRC is used to
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with a 72 bits of user information. Forward error correction is
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detect and eliminate most false decodes at the receiver. The resulting
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implemented by first augmenting the 72 message bits with an 8-bit CRC
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80-bit augmented message is mapped to a 128-bit codeword using a
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calculated from the message bits. The CRC is used to detect and
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(128,80) binary low-density-parity-check (LDPC) code designed by K9AN
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eliminate most false decodes at the receiver. The resulting 80-bit
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augmented message is then mapped to a 128-bit codeword using a
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(128,80) binary low-density-parity-check (LDPC) code designed
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specifically for this purpose. Two 8-bit synchronizing sequences are
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specifically for this purpose. Two 8-bit synchronizing sequences are
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added to make a message frame 144 bits long. Modulation is Offset
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added to make a message frame 144 bits long. Modulation is Offset
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Quadrature Phase-Shift Keying (OQPSK) at 2000 baud. Even-numbered bits
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Quadrature Phase-Shift Keying (OQPSK) at 2000 baud. Even-numbered bits
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are conveted over the in-phase channel, odd-numbered bits on the
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are conveyed over the in-phase channel, odd-numbered bits on the
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quadrature channel. Individual symbols are shaped with half-sine
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quadrature channel. Individual symbols are shaped with half-sine
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profiles, thereby ensuring a generated waveform with constant
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profiles, thereby ensuring a generated waveform with constant
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envelope, equivelent to a Minimum Shift Keying (MSK) waveform. Frame
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envelope, equivelent to a Minimum Shift Keying (MSK) waveform. Frame
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duration is 72 ms so the effective character transmission rate for
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duration is 72 ms, so the effective character transmission rate for
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standard messages is as high as 250 cps.
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standard messages is up to 250 cps.
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MSK144 also supports short-form messages that can be used after QSO
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MSK144 also supports short-form messages that can be used after QSO
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partners have exchanged callsigns. These consist of 4 bits that
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partners have exchanged both callsigns. Short messages consist of 4
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encode a signal report, R+report, RRR, or 73, together with a 12-bit
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bits encoding a signal report, R+report, RRR, or 73, together with a
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hash code based on the ordered pair of callsigns is use. A specially
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12-bit hash code based on the ordered pair of "`to`" and "`from`"
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designed LDPC (32,16) code provides error-correction, and an 8-bit
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callsigns. Another specially designed LDPC (32,16) code provides
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synchronizing vector is appended to make up a 40-bit frame.
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error correction, and an 8-bit synchronizing vector is appended to
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Short-message duration is thus 20 ms, and short messages can be
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make up a 40-bit frame. Short-message duration is thus 20 ms, and
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conveyed by very short meteor "pings".
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short messages can be decoded from very short meteor pings.
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As in the other fast modes in WSJT-X, the 72 ms or 20 ms frames of
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The 72 ms or 20 ms frames of MSK144 messages are repeated without gaps
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MSK144 messages are repeated without gaps for the full duration of a
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for the full duration of a transmission cycle. For most purposes, a
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transmission cycle. For most purposes, a cycle duration of 15s is
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cycle duration of 15 s is suitable and recommended for MSK144.
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||||||
recommended for MSK144.
|
|
||||||
|
|
||||||
The modulated MSK144 signal occupies the full bandwidth of a SSB
|
The modulated MSK144 signal occupies the full bandwidth of a SSB
|
||||||
transmitter, so transmissions are always centered on audio frequency
|
transmitter, so transmissions are always centered at audio frequency
|
||||||
1500 Hz. For best results, transmitter and receiver filters should be
|
1500 Hz. For best results, transmitter and receiver filters should be
|
||||||
adjusted to provide the flattest possible response over the range
|
adjusted to provide the flattest possible response over the range
|
||||||
300Hz to 2700Hz. Further, the maximum permissible frequency offset
|
300Hz to 2700Hz. The maximum permissible frequency offset between you
|
||||||
between you and your QSO partner should be ± 100 Hz.
|
and your QSO partner ± 200 Hz.
|
||||||
|
|
||||||
Details:
|
=== Fast Modes
|
||||||
|
|
||||||
Standard 72ms MSK frames contain 144 bits and consist of a standard
|
|
||||||
JT-mode 72-bit message augmented with 56 bits for error detection and
|
|
||||||
correction. The 72+56=128-bit codeword is combined with two 8-bit sync
|
|
||||||
words to form a 144-bit frame. The frame is constructed as
|
|
||||||
S8,D48,S8,D80, where S8 represents an 8-bit sync word and D48,D80
|
|
||||||
represent the first 48 bits and last 80 bits of the 128-bit codeword,
|
|
||||||
respectively. (At present, the 128-bit codeword is re-ordered to put
|
|
||||||
even/odd bits at the beginning/end of the codeword — this is a
|
|
||||||
holdover from JTMSK and is probably not necessary.) The 144-bit frame
|
|
||||||
is repeated for the duration of a transmission cycle.
|
|
||||||
|
|
||||||
|
|
||||||
=== Summary
|
|
||||||
|
|
||||||
[[SLOW_TAB]]
|
|
||||||
.Parameters of Slow Modes
|
|
||||||
[width="90%",cols="3h,^3,^2,^1,^2,^2,^2,^2,^2,^2",frame=topbot,options="header"]
|
|
||||||
|===============================================================================
|
|
||||||
|Mode |FEC Type |(k,n) | Q| Mod | Baud |BW (Hz)|fSync|TxT (s)|S/N (dB)
|
|
||||||
|JT4A |K=32, r=1/2|(206,72)| 2| 4-FSK| 4.375| 17.5 | 0.50| 47.1 | -23
|
|
||||||
|JT9A |K=13, r=1/2|(206,72)| 8| 9-FSK| 1.736| 15.6 | 0.19| 49.0 | -27
|
|
||||||
|JT65A |RS |(63,12) |64|65-FSK| 2.692| 177.6 | 0.50| 46.8 | -25
|
|
||||||
|QRA64A|QRA |(63,12) |64|64-FSK| 1.736| 111.1 | 0.25| 48.4 | -28
|
|
||||||
| WSPR |K=32, r=1/2|(162,50)| 2| 4-FSK| 1.465| 5.9 | 0.50|110.6 | -29
|
|
||||||
|===============================================================================
|
|
||||||
|
|
||||||
.Parameters of Fast Modes
|
.Parameters of Fast Modes
|
||||||
[width="90%",cols="3h,^3,^2,^1,^2,^2,^2,^2,^2,^2",frame="topbot",options="header"]
|
[width="90%",cols="3h,^3,^2,^1,^2,^2,^2,^2,^2,^2",frame="topbot",options="header"]
|
||||||
|
@ -116,7 +116,7 @@ averaging* over successive transmissions and/or correlation decoding,
|
|||||||
image::decoding_depth.png[align="center",alt="Decoding Depth"]
|
image::decoding_depth.png[align="center",alt="Decoding Depth"]
|
||||||
|
|
||||||
IMPORTANT: Additional hints for using JT4 and Echo mode on the
|
IMPORTANT: Additional hints for using JT4 and Echo mode on the
|
||||||
EME path have been compiled by G3WDG and are available here: {jt4eme}.
|
*EME path have been compiled by G3WDG and are available here: {jt4eme}.
|
||||||
|
|
||||||
=== JT65
|
=== JT65
|
||||||
|
|
||||||
@ -142,6 +142,14 @@ _WSJT-X_, Version 1.7. The protocol is still subject to change, and
|
|||||||
some features of the decoder will likely change. In most ways
|
some features of the decoder will likely change. In most ways
|
||||||
operation of QRA64 is similar to JT65.
|
operation of QRA64 is similar to JT65.
|
||||||
|
|
||||||
|
=== ISCAT
|
||||||
|
|
||||||
|
ISCAT is a useful mode for signals that are weak but more or less
|
||||||
|
steady in amplitude, at least for several seconds. Aircraft scatter
|
||||||
|
at 10 GHz is a good example. ISCAT messages are free-format and may
|
||||||
|
have any length from 1 to 28 characters. The protocol includes no
|
||||||
|
error-correction facility.
|
||||||
|
|
||||||
=== MSK144
|
=== MSK144
|
||||||
|
|
||||||
Meteor-scatter QSOs can be made any time on the VHF bands at distances
|
Meteor-scatter QSOs can be made any time on the VHF bands at distances
|
||||||
@ -199,10 +207,6 @@ IMPORTANT: There is little or no advantage to using MSK144 *Sh*
|
|||||||
messages at 50 or 70 MHz. At these frequencies most pings are long
|
messages at 50 or 70 MHz. At these frequencies most pings are long
|
||||||
enough to support standard messages.
|
enough to support standard messages.
|
||||||
|
|
||||||
=== Scatter Propagation with ISCAT
|
|
||||||
|
|
||||||
TBD ...
|
|
||||||
|
|
||||||
=== Echo Mode
|
=== Echo Mode
|
||||||
|
|
||||||
*Echo* mode allows you to make sensitive measurements of your own
|
*Echo* mode allows you to make sensitive measurements of your own
|
||||||
|
@ -148,10 +148,6 @@ include::wspr.adoc[]
|
|||||||
[[COMMAND_REF]]
|
[[COMMAND_REF]]
|
||||||
== On-Screen Controls
|
== On-Screen Controls
|
||||||
|
|
||||||
[[CONTROLS_WIDE]]
|
|
||||||
=== Wide Graph
|
|
||||||
include::controls-functions-wide-graph.adoc[]
|
|
||||||
|
|
||||||
[[CONTROLS_MAIN]]
|
[[CONTROLS_MAIN]]
|
||||||
=== Main Window
|
=== Main Window
|
||||||
include::controls-functions-main-window.adoc[]
|
include::controls-functions-main-window.adoc[]
|
||||||
@ -176,6 +172,10 @@ include::controls-functions-status-bar.adoc[]
|
|||||||
=== Menus
|
=== Menus
|
||||||
include::controls-functions-menus.adoc[]
|
include::controls-functions-menus.adoc[]
|
||||||
|
|
||||||
|
[[CONTROLS_WIDE]]
|
||||||
|
=== Wide Graph
|
||||||
|
include::controls-functions-wide-graph.adoc[]
|
||||||
|
|
||||||
[[LOGGING]]
|
[[LOGGING]]
|
||||||
== Logging
|
== Logging
|
||||||
include::logging.adoc[]
|
include::logging.adoc[]
|
||||||
@ -201,19 +201,20 @@ include::protocols.adoc[]
|
|||||||
== Astronomical Data
|
== Astronomical Data
|
||||||
include::astro_data.adoc[]
|
include::astro_data.adoc[]
|
||||||
|
|
||||||
|
|
||||||
|
////
|
||||||
[[TXRX]]
|
[[TXRX]]
|
||||||
== Implementation Details
|
== Implementation Details
|
||||||
include::implementation.adoc[]
|
include::implementation.adoc[]
|
||||||
|
|
||||||
////
|
|
||||||
[[TROUBLE_SHOOTING]]
|
[[TROUBLE_SHOOTING]]
|
||||||
== Troubleshooting
|
== Troubleshooting
|
||||||
To be added (?) ...
|
To be added (?) ...
|
||||||
////
|
|
||||||
|
|
||||||
[[UTIL]]
|
[[UTIL]]
|
||||||
== Utility Programs
|
== Utility Programs
|
||||||
include::utilities.adoc[]
|
include::utilities.adoc[]
|
||||||
|
////
|
||||||
|
|
||||||
[[SUPPORT]]
|
[[SUPPORT]]
|
||||||
== Support
|
== Support
|
||||||
|
Loading…
Reference in New Issue
Block a user