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15    <h3>GPSD NG client driver</h3>
16<p>Last update:
17  <!-- #BeginDate format:En2m -->30-Apr-2015  05:53<!-- #EndDate -->
18  UTC</p>
19    <hr>
20    <h4>Synopsis</h4>
21
22    <p>
23      Address: 127.127.46.<i>u</i><br>
24      Reference ID: <tt>GPSD</tt><br>
25      Driver ID: <tt>GPSD_JSON</tt><br>
26      Serial Port: <tt>/dev/gps<i>u</i></tt> as symlink to the true
27      device (not used directly; see below)<br>
28      Features: <tt></tt>
29    </p>
30
31    <!-- --------------------------------------------------------- -->
32
33    <br><h4>Description</h4>
34    <p>
35      This driver is a client driver to the <i>GPSD</i> daemon, which
36      over the time became increasingly popular for UN*Xish
37      platforms. <i>GPSD</i> can manage several devices in parallel,
38      aggregate information, and acts as a data hub for client
39      applications. <i>GPSD</i> can also auto-detect and handle PPS
40      hardware signals on serial ports. Have a look
41      at <a href="http://www.catb.org/gpsd/">the
42      <i>GPSD</i> project page</a>.
43    </p>
44    <p>
45      <b>It is important to understand that this driver works best
46      using a GPS device with PPS support.</b>
47    </p>
48    <p>
49      The GPSD-NG protocol is text based, using JSON notation to
50      transfer records in form of JSON objects. The driver uses a
51      TCP/IP connection to <tt>localhost:gpsd</tt> to connect to the
52      daemon and then requests the GPS
53      device <tt>/dev/gps<i>u</i></tt> to be watched. (Different clock
54      units use different devices, and
55      <i>GPSD</i> is able to give only the relevant information to a clock
56      instance.)
57    </p>
58    <p>
59      This driver does not expect <i>GPSD</i> to be running or the
60      clock device to be present <i>a priori</i>; it will try to
61      re-establish a lost or hitherto unsuccessful connection and will
62      wait for device to come up in <i>GPSD.</i> There is an initial
63      10 seconds delay between a connection loss or failed attempt and
64      the next reconnect attempt; this makes sure that there is no
65      thrashing on the network layer. If the connection fails again,
66      an exponential back off is used with an upper limit of
67      approximately 10 minutes.
68    </p>
69    <p>
70      The overall accuracy depends on the receiver used. The driver
71      uses the error estimations (95% probability limits) provided by
72      <i>GPSD</i> to set the clock precision dynamically according to
73      these readings.
74    </p>
75    <p>
76      The driver needs the VERSION, TPV, PPS, WATCH and TOFF objects
77      of the <i>GPSD</i> protocol. (Others are quietly ignored.) The
78      driver can operate without the TOFF objects, which are available
79      with the <i>protocol</i> version 3.10 and above. (Not to be
80      confused with the <i>release</i> version of <i>GPSD</i>!)
81      Running without TOFF objects has a negative impact on the jitter
82      and offset of the serial timing information; if possible, a
83      version of <i>GPSD</i> with support for TOFF objects should be
84      used.
85    </p>
86    <p>The acronym <u>STI</u> is used here as a synonym for <i>serial
87      time information</i> from the data channel of the receiver, no
88      matter what objects were used to obtain it.
89    </p>
90
91    <!-- --------------------------------------------------------- -->
92
93    <br><h4>Naming a Device</h4>
94    <p>
95      The <i>GPSD</i> driver uses the same device name as the NMEA
96      driver, namely <tt>/dev/gps<i>u</i></tt>. There is a simple
97      reason for that: While the NMEA driver and the <i>GPSD</i>
98      driver can be active at the same time <b>for different
99      devices</b>, they cannot access the same device at a
100      time. Having the same name helps on that. It also eases
101      migration from using NMEA directly to using <i>GPSD</i>, as no
102      new links etc need to be created.
103    </p>
104    <p>
105      <i>GPSD</i> is normally started with the device name to access;
106      it can also be instructed by hot-plug scripts to add or remove
107      devices from its device pool. Luckily, the symlinks used by the
108      NMEA driver are happily accepted and used by <i>GPSD</i>; this
109      makes it possible to use the symlink names as device
110      identification. This makes the migration from the built-in NMEA
111      driver a bit easier.
112    </p>
113    <p><b>Note:</b> <i>GPSD</i> (as of version 3.10) cannot use kernel
114      mode PPS on devices that are hot-plugged. This would require to
115      attach the PPS line discipline to the character special file,
116      which is not possible when running with root privileges already
117      dropped. This is not likely to change in the future.
118    </p>
119
120    <!-- --------------------------------------------------------- -->
121
122    <br><h4>The 'mode' word</h4>
123    <p>
124      A few operation modes can be selected with the mode word.
125    </p>
126    <p>
127      <table border="1" frame="box" rules="all">
128      <th colspan="3">The Mode Word</th>
129	<tr> <td>Bits</td><td>Value</td><td>Description</td>
130	</tr>
131	<tr> <td rowspan="4"align="center">0..1</td>
132	  <td align="center">0</td>
133	  <td>STI only operation. This mode is affected by the timing
134	    stability of whatever protocol is used between the GPS
135	    device and GPSD.
136	    <br>
137	    Running on STI only is not recommended in general. Possible
138	    use cases include:
139	    <ul>
140	      <li>The receiver does not provide a PPS signal.
141	      <li>The receiver <i>does</i> provide a PPS signal and
142	      the secondary PPS unit is used.
143	      <li>The receiver has a stable serial timing and a proper
144	      fudge can be established.
145	      <li>You have other time sources available and want to
146		establish a useful fudge value for <tt>time2</tt>.
147	    </ul>
148	  </td>
149	</tr>
150	<tr>
151	  <td align="center">1</td>
152	  <td>Strict operation. This mode needs a valid PPS and a
153	    valid STI to combine the absolute time from the STI with
154	    the time stamp from the PPS record. Does not feed clock
155	    samples if no valid PPS+STI pair is available.
156	    <br><br>
157	    This type of operation results in an ordinary clock with a
158	    very low jitter as long as the PPS data is available, but
159	    the clock fails once PPS drops out. This mode is a
160	    possible choice for receivers that provide a PPS signal
161	    most of the time but have an unstable serial timing that
162	    cannot be fudge-compensated.
163	  </td>
164	</tr>
165	<tr><td align="center">2</td>
166	  <td>Automatic mode. Tries to operate in strict mode unless
167	    it fails to process valid samples for some time, currently
168	    120s. Then it reverts to STI-only operation until the PPS
169	    is stable again for 40s, when strict mode is engaged
170	    again.
171	    <br><br><b>Important Notice: This is an expiremental
172	    feature!</b><br>  Switching between strict and STI-only
173	    mode will cause changes in offset and jitter. Use this
174	    mode only if STI-only works fairly well with your setup,
175	    or if you expect longer dropouts of the PPS signal and
176	    prefer to use STI alone over not getting synchronised at
177	    all.</td>
178	</tr>
179	<tr>
180	  <td align="center">3</td>
181	  <td><i>(reserved for future extension, do not use)</i></td>
182	</tr>
183	<tr>
184	  <td align="center">2..31</td>
185	  <td colspan="2"><i>(reserved for future extension, do not
186	  use)</i></td>
187	</tr>
188      </table>
189    </p>
190
191    <!-- --------------------------------------------------------- -->
192
193    <br><h4>Syslog flood throttle</h4>
194    <p>This driver can create a lot of syslog messages when things go
195      wrong, and cluttering the log files is frowned upon. So we
196      attempt to log persistent or recurring errors only once per
197      hour. On the other hand, when tracking a problem the syslog
198      flood throttle can get into the way.</p>
199    <p>Therefore, fudge <i>flag3</i> can be used to <i>disable</i> the
200      flood throttle at any time; the throttle is engaged by
201      default. Running with the syslog flood throttle disabled for
202      lengthy time is not recommended unless the log files are closely
203      monitored.</p>
204
205    <!-- --------------------------------------------------------- -->
206
207    <br><h4>PPS secondary clock unit</h4>
208    <p>Units with numbers &ge;128 act as secondary clock unit for the
209      primary clock unit (u mod 128). A secondary unit processes only
210      the PPS data from <i>GPSD</i> and needs the corresponding master
211      unit to work<a href="#fn1" name="fn1bl"><sup>1</sup></a>. Use
212      the 'noselect' keyword on the primary unit if you are not
213      interested in its data.
214    </p><p>The secondary unit employs the usual precautions before
215      feeding clock samples:</p>
216    <ul>
217      <li>The system must be already in a synchronised state.
218      <li>The system offset must be less than 400ms absolute.
219      <li>The phase adjustment from the PPS signal must also be less
220	than 400ms absolute.
221    </ul>
222    <p>If fudge flag <tt>flag1</tt> is set for the secondary unit, the
223      unit asserts the PPS flag on the clock as long as PPS data is
224      available. This makes the unit eligible as PPS peer and should
225      only be used if the GPS receiver can be trusted for the quality
226      of its PPS signal<a href="fn2"
227      name="fn2bl"><sup>2</sup></a>. The PPS flag gets cleared if no
228      PPS records can be aquired for some time. The unit also flushes
229      the sample buffer at this point to avoid the use of stale PPS
230      data.</p>
231    <p><b>Attention:</b> This unit uses its own PPS fudge value
232      which must be set as fudge <tt>time1</tt>. Only the fudge
233      values <tt>time1</tt> and <tt>flag1</tt> have an impact on secondary
234      units.</p>
235
236    <!-- --------------------------------------------------------- -->
237
238    <br><h4>Clockstats</h4>
239    <p>If flag4 is set when the driver is polled, a clockstats record
240      is written for the primary clock unit. (The secondary PPS unit
241      does not provide clock stats on its own.) The first 3 fields are
242      the normal date, time, and IP address common to all clockstats
243      records.
244    </p><p>
245      <table border="1" frame="box" rules="all">
246	<th colspan="2">The Clockstats Line</th>
247	<tr> <td>field</td><td>Description</td>	</tr>
248	<tr>
249	  <td align="center">1</td>
250	  <td>Date as day number since NTP epoch.</td>
251	</tr><tr>
252	  <td align="center">2</td>
253	  <td>Time as seconds since midnight.</td>
254	</tr><tr>
255	  <td align="center">3</td>
256	  <td>(Pseudo-) IP address of clock unit.</td>
257	</tr><tr>
258	  <td align="center">4</td>
259	  <td>Number of received known JSON records since last
260	    poll. The driver knows about TPV, PPS, TOFF, VERSION and
261	    WATCH records; others are silently ignored.
262	  </td>
263	</tr><tr>
264	  <td align="center">5</td>
265	  <td>Bad replies since last poll. A record is considered
266	    malformed or a bad reply when it is missing vital fields
267	    or the fields contain malformed data that cannot be
268	    parsed.
269	  </td>
270	</tr><tr>
271	  <td align="center">6</td>
272	  <td>Number of sample cycles since last poll that were
273	    discarded because there was no GPS fix. This is
274	    effectively the number of TPV records with a fix value
275	    &lt; 2 or without a time stamp.
276	  </td>
277	</tr><tr>
278	  <td align="center">7</td>
279	  <td>Number of serial time information records (TPV or TOFF,
280	    depending on the GPSD version) received since last poll.
281	  </td>
282	</tr><tr>
283	  <td align="center">8</td>
284	  <td>Number of serial time information records used for
285	    clock samples since the last poll.
286	  </td>
287	</tr><tr>
288	  <td align="center">9</td>
289	  <td>Number of PPS records received since the last poll.</td>
290	</tr><tr>
291	  <td align="center">10</td>
292	  <td>Number of PPS records used for clock samples on the
293	    secondary channel since the last poll.
294	  </td>
295	</tr>
296      </table>
297    </p>
298
299    <!-- --------------------------------------------------------- -->
300
301    <br><h4>Fudge Factors</h4>
302
303    <dl>
304      <dt><tt>time1 <i>time</i></tt></dt>
305      <dd>Specifies the PPS time offset calibration factor, in seconds
306      and fraction, with default 0.0.</dd>
307      <dt><a name="fudgetime2"><tt>time2 <i>time</i></tt></a></dt>
308      <dd><em>[Primary Unit]</em> Specifies the TPV/TIME time offset
309      calibration factor, in seconds and fraction, with default
310      0.0.</dd>
311      <dt><tt>stratum <i>number</i></tt></dt>
312      <dd>Specifies the driver stratum, in decimal from 0 to 15, with
313	default 0.</dd>
314      <dt><tt>refid <i>string</i></tt></dt>
315      <dd>Specifies the driver reference identifier, an ASCII string
316	from one to four characters, with default <tt>GPSD</tt>.</dd>
317      <dt><tt>flag1 0 | 1</tt></dt><dd><em>[<b>Secondary</b>
318	  Unit]</em> When set, flags the secondary clock unit as a
319	potential PPS peer as long as good PPS data is available.
320      </dd>
321      <dt><tt>flag2 0 | 1</tt></dt>
322      <dd><em>[Primary Unit]</em> When set, <u>disables</u> the
323	processing of incoming PPS records. Intended as an aide to
324	test the effects of a PPS dropout when using automatic mode
325	(mode 2).
326      </dd>
327      <dt><tt>flag3 0 | 1</tt></dt><dd><em>[Primary Unit]</em>
328      If set, <u>disables</u> the log throttle. Useful when tracking
329      problems in the interaction between <i>GPSD</i> and <i>NTPD</i>,
330      since now all error events are logged. Persistent/recurrent
331      errors can easily fill up the log, so this should only be
332      enabled during bug hunts.</dd>
333      <dt><tt>flag4 0 | 1</tt></dt><dd><em>[Primary Unit]</em>
334	If set, write a clock stats line on every poll cycle.
335      </dd>
336    </dl>
337
338    <!-- -- footnotes -------------------------------------------- -->
339
340    <hr>
341    <p><a name="fn1" href="#fn1bl"><sup>1</sup>) </a>Data transmission
342      an decoding is done only once by the primary unit. The decoded
343      data is then processed independently in both clock units. This
344      avoids double transmission over two sockets and decoding the
345      same data twice, but the primary unit is always needed as a
346      downside of this approach.
347    </p>
348    <p><a name="fn2" href="#fn2bl"><sup>2</sup>) </a>The clock driver
349      suppresses the processing PPS records when the TPV/TIME data
350      indicates the receiver has no fix. It can also deal with
351      situations where the PPS signal is not delivered
352      to <i>GPSD</i>. But once it is available, it is also processed
353      and used to create samples. If a receiver cannot be trusted for
354      the precision of its PPS signal, it should not be used to create
355      a possible PPS peer: These get extra clout and can effectively
356      become the sole source of input for the control loop. You do not
357      want to use sloppy data for that.
358    <hr>
359    <p>Additional Information</p>
360    <p><a href="../refclock.html">Reference Clock Drivers</a></p>
361    <hr>
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