| This directory contains a simple python script for visualizing |
| the behavior of the WindowOrientationListener. |
| |
| |
| PREREQUISITES |
| ------------- |
| |
| 1. Python 2.6 |
| 2. numpy |
| 3. matplotlib |
| |
| |
| USAGE |
| ----- |
| |
| The tool works by scaping the debug log output from WindowOrientationListener |
| for interesting data and then plotting it. |
| |
| 1. Enable the Window Orientation Listener debugging data log using the |
| Development Settings in the Dev Tools application (Development.apk). |
| |
| 2. Plug in the device. Ensure that it is the only device plugged in |
| since this script is of very little brain and will get confused otherwise. |
| |
| 3. Run "orientationplot.py". |
| |
| 4. When finished, remember to disable the debug log output since it is quite verbose! |
| |
| |
| WHAT IT ALL MEANS |
| ----------------- |
| |
| The tool displays several time series graphs that plot the output of the |
| WindowOrientationListener. Here you can see the raw accelerometer data, |
| filtered accelerometer data, measured tilt and orientation angle, confidence |
| intervals for the proposed orientation and accelerometer latency. |
| |
| Things to look for: |
| |
| 1. Ensure the filtering is not too aggressive. If the filter cut-off frequency is |
| less than about 1Hz, then the filtered accelorometer data becomes too smooth |
| and the latency for orientation detection goes up. One way to observe this |
| is by holding the device vertically in one orientation then sharply turning |
| it 90 degrees to a different orientation. Compared the rapid changes in the |
| raw accelerometer data with the smoothed out filtered data. If the filtering |
| is too aggressive, the filter response may lag by hundreds of milliseconds. |
| |
| 2. Ensure that there is an appropriate gap between adjacent orientation angles |
| for hysteresis. Try holding the device in one orientation and slowly turning |
| it 90 degrees. Note that the confidence intervals will all drop to 0 at some |
| point in between the two orientations; that is the gap. The gap should be |
| observed between all adjacent pairs of orientations when turning the device |
| in either direction. |
| |
| Next try holding the device in one orientation and rapidly turning it end |
| over end to a midpoint about 45 degrees between two opposing orientations. |
| There should be no gap observed initially. The algorithm should pick one |
| of the orientations and settle into it (since it is obviously quite |
| different from the original orientation of the device). However, once it |
| settles, the confidence values should start trending to 0 again because |
| the measured orientation angle is now within the gap between the new |
| orientation and the adjacent orientation. |
| |
| In other words, the hysteresis gap applies only when the measured orientation |
| angle (say, 45 degrees) is between the current orientation's ideal angle |
| (say, 0 degrees) and an adjacent orientation's ideal angle (say, 90 degrees). |
| |
| 3. Accelerometer jitter. The accelerometer latency graph displays the interval |
| between sensor events as reported by the SensorEvent.timestamp field. It |
| should be a fairly constant 60ms. If the latency jumps around wildly or |
| greatly exceeds 60ms then there is a problem with the accelerometer or the |
| sensor manager. |
| |
| 4. The orientation angle is not measured when the tilt is too close to 90 or -90 |
| degrees (refer to MAX_TILT constant). Consequently, you should expect there |
| to be no data. Likewise, all dependent calculations are suppressed in this case |
| so there will be no orientation proposal either. |
| |
| 5. Each orientation has its own bound on allowable tilt angles. It's a good idea to |
| verify that these limits are being enforced by gradually varying the tilt of |
| the device until it is inside/outside the limit for each orientation. |
| |
| 6. Orientation changes should be significantly harder when the device is held |
| overhead. People reading on tablets in bed often have their head turned |
| a little to the side, or they hold the device loosely so its orientation |
| can be a bit unusual. The tilt is a good indicator of whether the device is |
| overhead. |