#!/usr/bin/python from tmc.wave import * from tmc.dxplore import dxplore from tmc.decode import d_usb_stream # # Clock recovery: we assume that each change in the wave is triggered by a # clock edge. We know the clock's nominal period and resynchronize on each # edge. Additionally, we can obtain a list of times when a timing violation # has occurred. # # Note that the timing violations logic doesn't make much sense in its present # form, since it mainly measures noise (particularly if we're digitizing slow # edges) and not clock drift. # # A more useful metric would be accumulated error from some point of reference # or at least the timing of same edges, to eliminate (generally harmless) time # offsets introduced by digitizing. # # So it would probably make more sense for "recover" not to check for timing # violations at all, and leave this to more specialized functions. # def recover(self, period, min = None, max = None, t0 = None): if t0 is None: t0 = self.data[0] v = not self.initial res = [] violations = [] for t in self.data: v = not v if t <= t0: continue n = 0 while t0 < t-period/2: res.append(t0) t0 += period n += 1 if min is not None: if t0-t > n*min: violations.append(t) if max is not None: if t-t0 > n*max: violations.append(t) t0 = t return res, violations # # Load the analog waves saved by get.py # wv = waves() wv.load("_wv") # # Digitize the waves and save the result. # dm = wv[0].digitize(1.5, 1.8) dp = wv[1].digitize(1.5, 1.8) wv = waves(dp, dm, dp-dm) wv.save("_dig") # # Also record the differential signal. # wd = wv[1]-wv[0] dd = wd.digitize(-0.5, 0.5) wd.save("_diff") # # Run clock recovery on D+/D-. We only need one, but check both to be sure. # #p = 1/1.5e6 p = 1/12e6 dp_t, viol = recover(dp, p, p*0.9, p*1.1) print viol dm_t, viol = recover(dm, p, p*.9, p*1.1, t0 = dp.data[0]) print viol # # Shift the clock by half a period, add a few periods to get steady state and # SE0s (if any), and then sample the data lines. # clk = map(lambda t: t+p/2, dp_t) clk.extend((clk[-1]+p, clk[-1]+2*p, clk[-1]+3*p)) dp_bv = dp.get(clk) dm_bv = dm.get(clk) # # Save a wave with the recovered clock to make it easier to find the bits in # analog graphs. # dd.data = dp_t; dd.save("_clk") # # For decoding, we need a fake bit clock. We generate it by doubling each data # bit and generating a L->H transition during this bit. # dpd = [] dmd = [] dck = [] # err, silly, seems that we've mixed up D+ and D- all over the place :-) print d_usb_stream(dm_bv[:], dp_bv[:]) for v in dp_bv: dpd.append(v) dpd.append(v) dck.append(0) dck.append(1) for v in dm_bv: dmd.append(v) dmd.append(v) # # Display the reconstructed digital signal. Note that the absolute time is only # correct at the beginning and that relative time is only accurate over # intervals in which no significant clock resynchronization has occurred. # # In fact, dxplore should probably have an option to either turn off time # entirely or to display a user-provided time axis. The latter may be a bit # tricky to implement. # dxplore((dmd, dpd, dck), 0, p/2, labels = ("D+", "D-", "CLK"))