diff --git a/README.rst b/README.rst
index 8b0f9d9..bb92c25 100644
--- a/README.rst
+++ b/README.rst
@@ -4,19 +4,18 @@ Watch Application System in Python
 Introduction
 ------------
 
-Although still in its infancy wasp-os provides many example applications
-including a simple digital clock, a stopwatch, a step counter and a heart rate
-monitor. All of these, together with access to the MicroPython REPL for
-interactive tweaking and testing, are running on `PineTime
-<https://www.pine64.org/pinetime/>`_.  It keeps time well and has enough power
-saving functions implemented that it can survive for well over 72 hours between
-charges so even at this early stage it is functional as a wearable timepiece.
+Wasp-os is a firmware for smart watches that are based on the nRF52
+family of microcontrollers, including hacker friendly watches such
+as the Pine64 PineTime. Wasp-os includes a digital clock, a stopwatch,
+a step counter and a heart rate monitor. All of these, together with
+access to the MicroPython REPL for interactive tweaking, development
+and testing.
 
 Wasp-os includes a robust bootloader based on the Adafruit NRF52
 Bootloader. It has been extended to make it robust for development on
 form-factor devices without a reset button, power switch, SWD debugger
 or UART. This allows us to confidently develop on sealed devices relying
-only on BLE for updates.
+on Bluetooth Low Energy for over-the-air updates.
 
 Documentation
 -------------
@@ -29,19 +28,19 @@ get started coding for wasp-os as quickly as possible.
 Getting Started
 ---------------
 
-Wasp-os can be installed without using any tools onto the following
-devices:
+Wasp-os can be installed without using any tools or disassembly onto the
+following devices:
 
- * Pine64 PineTime (developer edition)
+ * Pine64 PineTime
  * Colmi P8
  * Senbono K9
 
-The
+Use the
 `Installation Guide <https://wasp-os.readthedocs.io/en/latest/install.html>`_
-contains detailed instructions on how to build and install wasp-os.
+to learn how to build and install wasp-os on these devices.
 
 At the end of the install process your watch will show the time (03:00)
-together with a date and battery meter. When the watch goes into power
+together with a date and a battery meter. When the watch goes into power
 saving mode you can use the button to wake it again.
 
 At this point you will also be able to use the Nordic UART Service to
@@ -56,7 +55,7 @@ To set the time and restart the main application:
    watch.rtc.set_localtime((yyyy, mm, dd, HH, MM, SS))
    wasp.system.run()
 
-Or just use:
+Or, if you have a suitable GNU/Linux workstation, just use:
 
 .. code-block:: sh
 
@@ -103,10 +102,12 @@ Videos
 Screenshots
 -----------
 
-(An older version of) the digital clock application running on a Pine64 PineTime:
+(An older version of) the digital clock application running on a Pine64
+PineTime:
 
 .. image:: res/clock_app.jpg
    :alt: wasp-os digital clock app running on PineTime
+   :width: 233
 
 Screenshots of the built in applications running on the wasp-os
 simulator (the "blank" screen is the torch application):
@@ -163,6 +164,6 @@ using one of the techniques is the Application Writer's guide.
    :alt: Game of Life running in the wasp-os simulator
    :width: 179
 
-.. image:: res/MusicPlayerApp.png
+.. image:: res/MusicApp.png
    :alt: Music Player running in the wasp-os simulator
    :width: 179
diff --git a/TODO.rst b/TODO.rst
index 9957ead..f0b5f48 100644
--- a/TODO.rst
+++ b/TODO.rst
@@ -11,9 +11,7 @@ Roadmap
 --------------------------------
 
 For 0.4 we focus on improving the watch/phone integration whilst also taking steps
-to improve the general fit and finish. In addition the reloader will be extended
-to ensure we retain the capability to install wasp-os over-the-air on newer
-PineTime models.
+to improve the general fit and finish.
 
 Bootloader
 ~~~~~~~~~~
diff --git a/docs/appguide.rst b/docs/appguide.rst
index 3e71b78..142c898 100644
--- a/docs/appguide.rst
+++ b/docs/appguide.rst
@@ -14,7 +14,7 @@ roadmap: make writing applications easy (and fun).
 Applications that can be loaded, changed, adapted and remixed by the user
 are what **really** distinguishes a smart watch from a "feature watch"[#]_.
 In other words if we want a watch built around a tiny microcontroller to be
-sufficiently "smart" then it has to be all about the applications.
+"smart" then it has to be all about the applications.
 
 This guide will help you get started writing applications for wasp-os. Have fun!
 
@@ -22,7 +22,7 @@ This guide will help you get started writing applications for wasp-os. Have fun!
    took over the industry were retrospectively renamed "feature phones" to
    distinguish them from newer devices. Many of them were superficially similar
    to early Android devices but is was the application ecosystem that really
-   made smart phones smart.
+   made smart phones into what they are today.
 
 Hello World for wasp-os
 ~~~~~~~~~~~~~~~~~~~~~~~
@@ -32,16 +32,16 @@ Let's start by examining a simple "Hello, World!" application for wasp-os.
 .. literalinclude:: hello.py
    :linenos:
 
-There are a couple of points of interest:
+Some of the key points of interest in this example application are:
 
 1. Applications have a :py:attr:`~.TemplateApp.NAME`, which is shown in the
    launcher. Most applications also provide an :py:attr:`~.TemplateApp.ICON`
-   but a default is displayed if this is omitted.
-2. This example uses :py:meth:`~.TemplateApp.__init__` to initialize 
-   the state of the application, this ensure the state remains "sticky" 
-   when the application is activated and deactivated.
+   but a default will be displayed if this is omitted.
+2. This example uses :py:meth:`~.TemplateApp.__init__` to initialize
+   the state of the application, these variables are used to remember
+   the state of the application when when it is deactivated.
 3. :py:meth:`~.TemplateApp.foreground` is the only mandatory application entry
-   point and is responsible for redrawing the screen. This application does
+   point and it is responsible for redrawing the screen. This application does
    not implement :py:meth:`~.TemplateApp.background` because there is nothing
    for us to do!
 4. The use of :py:meth:`~.TemplateApp._draw` is optional. We could just do
@@ -55,10 +55,11 @@ Application life-cycle
 Applications in wasp-os are triggered by and do all their processing
 from calls their entry points. The entry points can be coarsely categorized
 event notifications, timer callbacks (the application tick) and
-system notifications.
+system actions.
 
-System notifications control the application life-cycle and the entry point
-calls, together with the implicit application states are shown below.
+System actions control the application life-cycle and that lifecyle is
+shown below. The system actions are used to tell the application about
+any change in its lifecycle.
 
 .. graphviz::
 
@@ -80,56 +81,66 @@ calls, together with the implicit application states are shown below.
     }
 
 When an application is initialized is enters the ``BACKGROUND`` state. A
-backgrounded application will not execute but it should nevertheless 
-maintain its user visible state whilst in the background. To conserve
+backgrounded application will not execute but it should nevertheless
+maintain its user visible state whilst deactivated. To conserve
 memory wasp-os does not permit two applications to run simultaneously but
-because each application preserves its state when in the background it will
-appear to the user as though all applications are running all the time.
+because each application remembers its state when it is not running then it
+will appear to the user as though all applications are running all the time.
 
 For example, a stopwatch application should record the time that it was started
-and remember that start time, regardless of it's state, until either the
-stopwatch is stopped of the application is destroyed.
+and remember that start time, regardless of whether it is running or not so
+that when it restarted is can continue to run as the user expects.
 
-A backgrounded application can enter the ``ACTIVE`` state via a call to
+A backgrounded application enters the ``ACTIVE`` state via a call to
 :py:meth:`~.TemplateApp.foreground`. When it is active the application owns the
-screen and should draw and maintain its UI.
+screen and must draw and maintain its user interface.
 
-If the system manager want to put an active application to sleep then it will
-call :py:meth:`~.TemplateApp.sleep`. If the application returns True then the
-application will stop running (e.g. receive no events and no application tick)
-but instead must wait to receive a notification via
-:py:meth:`~.TemplateApp.wake` telling the application that the device 
-is waking up and that it may update the screen if needed.
+If the system manager wants to put the watch to sleep then it will tell the
+active application to :py:meth:`~.TemplateApp.sleep`.
+If the application returns True then the application will remain active
+whilst the watch is asleep.
+It will receive no events nor the application tick whilst the system is
+asleep and, instead, must wait for a :py:meth:`~.TemplateApp.wake` notification
+telling the application that the device is waking up and that it may
+update the screen if needed.
 
 If an application does not support sleeping then it can simply not implement
-:py:meth:`~.TemplateApp.sleep` (or :py:meth:`~.TemplateApp.wake`) although it
-can also return False from :py:meth:`~.TemplateApp.sleep` if this is preferred.
+:py:meth:`~.TemplateApp.sleep` or :py:meth:`~.TemplateApp.wake`.
 In this case the system manager will automatically return to the default
 application, typically the main clock face.
 
+Some applications may support sleeping only under certain circumstances. For
+example a stopwatch may choose to remain active when the watch sleeps only if
+the stopwatch is running.
+This type of application must implement :py:meth:`~.TemplateApp.sleep` and
+return False when it does not want to remain active when the system
+resumes.
+
 .. note::
 
-    Most applications do not need to support :py:meth:`~.TemplateApp.sleep`
+    Most applications should not implement :py:meth:`~.TemplateApp.sleep`
     since it is often a better user experience for the watch to return to the
     default application when they complete an interaction.
-    
+
 API primer
 ----------
 
 This API primer introduces some of the most important and frequently used
-interfaces for wasp-os. For more comprehensive coverage see the
+interfaces in wasp-os. For more comprehensive coverage see the
 :ref:`Wasp-os Reference Manual` which contains extensive API documentation
 covering the entire of wasp-os, including its drivers.
 
 System management
 ~~~~~~~~~~~~~~~~~
 
-The system management API does provide a number of low-level calls that
+The system management API provides a number of low-level calls that
 can register new applications and navigate between them. However most
-applications need not use these. Instead most applications use a small
-set of methods. In particular almost all applictions need to call a couple of
-methods from :py:meth:`~.TemplateApp.foreground` in order to register 
-for notifications:
+applications do not need to make these low level calls and will use
+a much smaller set of methods.
+
+Applictions must call a couple of functions from their
+:py:meth:`~.TemplateApp.foreground` in order to register for
+event notifications and timer callbacks:
 
 * :py:meth:`~.Manager.request_event` - register for UI events such as button
   presses and touch screen activity.
@@ -137,8 +148,8 @@ for notifications:
   and specify the tick frequency.
 
 Additionally if your application is a game or a similar program that should
-not allow the watch to go to sleep then it should arrange to call
-:py:meth:`~.Manager.keep_awake` from the application's
+not allow the watch to go to sleep when it is running then it should
+arrange to call :py:meth:`~.Manager.keep_awake` from the application's
 :py:meth:`~.TemplateApp.tick` method.
 
 Drawing
@@ -148,8 +159,8 @@ Most applications using the drawing toolbox, :py:data:`wasp.watch.drawable`,
 in order to handle the display. Applications are permitted to directly access
 :py:data:`wasp.watch.display` if they require direct pixel access or want to
 exploit specific features of the display hardware (inverse video, partial
-display, etc) but for simple applications then the following simple drawing
-functions are sufficient.
+display, etc) but for most applications the drawing toolbox provides
+convenient and optimized drawing functions.
 
 * :py:meth:`~.Draw565.blit` - blit an image to the display at specified (x, y)
   coordinates, image type is detected automatically
@@ -186,7 +197,7 @@ MicroPython
 
 Many of the features of wasp-os are inherited directly from MicroPython_. It is
 useful to have a basic understanding of MicroPython and, in particular, put
-in a little time learning the best ways to copy with running
+a little time into learning the best practices when running
 `MicroPython on microcontrollers`__.
 
 .. _MicroPython: https://micropython.org/
@@ -201,10 +212,10 @@ How to run your application
 Testing on the simulator
 ~~~~~~~~~~~~~~~~~~~~~~~~
 
-wasp-os provides a simulator that can be used to test applications before
+wasp-os includes a simulator that can be used to test applications before
 downloading them to the device. The simulator is useful for ensuring the
 code is syntactically correct and that there are not major runtime problems
-(e.g. missing symbols).
+such as misspelt symbol names.
 
 .. note::
 
@@ -212,7 +223,7 @@ code is syntactically correct and that there are not major runtime problems
     device. It may still be necessary to tune the application for minimal
     footprint after testing on the simulator.
 
-Firstly launch the simulator:
+To launch the simulator:
 
 .. code-block:: sh
 
@@ -224,7 +235,7 @@ Firstly launch the simulator:
     Watch is running, use Ctrl-C to stop
 
 From the simulator console we can register the application with the following
-code:
+commands:
 
 .. code-block:: python
    :linenos:
@@ -240,19 +251,25 @@ code:
 
 When an application is registered it does not start automatically but it will
 have been added to the launcher and you will be able to select in the simulator
-by using the Arrow keys to bring up the launcher and then clicking on your
-application.
+by swiping or using the Arrow keys to bring up the launcher and then clicking
+on your application.
 
 The application can also be registered automatically when you load the
 simulator if you add it to ``wasp/main.py``. Try adding lines 5 and 6 from
 the above example into this file (between ``import wasp`` and
 ``wasp.system.run()``).
 
+The simulator accepts gestures such as up/down and left/right swipes but the
+simulator also accepts keystrokes for convenience. The arrow keys simulate
+swipes and the Tab key simulates the physical button, whilst the 's' key
+can be used to capture screen shots to add to the documentation for your
+application.
+
 Testing on the device
 ~~~~~~~~~~~~~~~~~~~~~
 
-If we have an application under development when we can launch a quick test
-that does not result in the application being permanently stored on the device.
+When an application is under development it is best to temporarily load
+your application without permanently stored on the device.
 Providing there is enough available RAM then this can lead to a very quick
 edit-test cycles.
 
@@ -264,11 +281,10 @@ Try:
             --exec myapp.py \\
             --eval "wasp.system.register(MyApp())"
     Preparing to run myapp.py:
-    [##################################################] 100% 
+    [##################################################] 100%
 
-Like the simulator, when an application is registered it does not start 
-automatically but it will have been added to the launcher and can be launched
-using the normal gestures to control the device.
+Like the simulator, when an application is registered it is added to the
+launcher and it does not start automatically.
 
 .. note::
 
@@ -276,19 +292,24 @@ using the normal gestures to control the device.
     application is too large to be compiled on the target. You may have to
     adopt the frozen module approach from the next section.
 
+To remove the application simply reboot the watch by pressing and
+holding the physical button until the watch enters OTA mode (this
+takes around five seconds). Once the watch is in OTA mode then
+press the phyiscal button again to return to normal mode with the
+application cleared out.
+
 Making it permanent
 ~~~~~~~~~~~~~~~~~~~
 
-To ensure you application survives a system reset (press the hardware 
-button for around five seconds until the splash screen is seen, wait 
-five seconds and then press again) then we must copy it to the device
-and ensure it gets launched during system startup.
+To ensure you application survives a reboot then we must copy it to the
+device and ensure it gets launched during system startup.
 
 .. note::
 
     Applications stored in external FLASH have a greater RAM overhead than
-    applications that are frozen into the wasp-os binary. See next section for
-    additional details.
+    applications that are frozen into the wasp-os binary. If you app does
+    not fix then see next section for additional details on how to embed
+    your app in the wasp-os binary itself..
 
 To copy your application to the external FLASH try:
 
@@ -296,7 +317,7 @@ To copy your application to the external FLASH try:
 
     sh$ ./tools/wasptool --upload myapp.py
     Uploading myapp.py:
-    [##################################################] 100% 
+    [##################################################] 100%
 
 At this point your application is stored on the external FLASH but it will
 not automatically be loaded. This requires you to update the ``main.py`` file
@@ -321,7 +342,7 @@ to the watch:
 
     sh$ ./tools/wasptool --upload wasp/main.py
     Uploading wasp/main.py:
-    [##################################################] 100% 
+    [##################################################] 100%
 
 .. note::
 
@@ -334,16 +355,16 @@ Freezing your application into the wasp-os binary
 ~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~~
 
 Freezing your application causes it to consume dramatically less RAM.  That is
-because the code is both pre-compiled (meaning we don't need any RAM budget to
-run the compiler) **and** it can execute directly from the internal FLASH
-memory.
+because they can execute directly from the internal FLASH rather than running
+from RAM. Additionally the code is pre-compiled, which also means we don't
+need any RAM budget to run the compiler.
 
-Freezing your application simply requires you to modify the ``manifest.py``
+Freezing your application requires you to modify the ``manifest.py``
 file for your board (e.g. ``wasp/boards/pinetime/manifest.py``) to include
 your application and then the whole binary must be re-compiled as normal.
 
-After that you an use the same technique described in the previous 
-section to add an import and register for you application to ``main.py``
+After that you an use the same technique described in the previous
+section to add an import and register for you application from ``main.py``
 
 .. note::
 
@@ -352,8 +373,10 @@ section to add an import and register for you application to ``main.py``
     external FLASH then the frozen version will be loaded.
 
     In many cases it is possible to avoid rebuilding the binary in order to
-    test new features by parsing the code in the global namespace and then
-    patching it into the existing code. For example the following can be used
+    test new features by directly parsing the code in the global
+    namespace (e.g. using ``wasptool --exec`` rather than ``wasptool --upload``
+    combined with ``import``). With the code in the global namespace it can
+    then be patched into the system. For example the following can be used
     to adopt a new version of the CST816S driver:
 
     .. code-block::
@@ -361,7 +384,7 @@ section to add an import and register for you application to ``main.py``
         ./tools/wasptool\
             --exec wasp/drivers/cst816s.py\
             --eval "watch.touch = CST816S(watch.i2c)"`
- 
+
 Application entry points
 ------------------------
 
diff --git a/docs/apps.rst b/docs/apps.rst
index 9decb62..b8fc67c 100644
--- a/docs/apps.rst
+++ b/docs/apps.rst
@@ -9,8 +9,8 @@ Application Library
 Built-in
 --------
 
-The built-in application are summarised below but since these apps are
-considers to be examples they are described in detail as part of the
+The built-in application are summarised below but because these apps are
+treated as examples they are described in detail as part of the
 :ref:`Wasp-os Reference Manual`: 
 
  * :py:class:`.ClockApp`
@@ -25,18 +25,20 @@ Watch faces
 
 .. automodule:: apps.fibonacci_clock
 
-This is enabled by default in the simulator. The app is bundled in the
-firmware image but it is disabled by default to keep RAM available for
-user developed applications. It can be enabled by modifying ``main.py``.
+This app is enabled by default in the simulator.
+The app is also frozen into the firmware image but it is disabled by
+default in order to keep RAM available for user developed applications.
+It can be enabled by modifying ``main.py``.
 
 Games
 -----
 
 .. automodule:: apps.gameoflife
 
-This is enabled by default in the simulator. The app is bundled in the
-firmware image but it is disabled by default to keep RAM available for
-user developed applications. It can be enabled by modifying ``main.py``.
+This app is enabled by default in the simulator.
+The app is also frozen into the firmware image but it is disabled by
+default in order to keep RAM available for user developed applications.
+It can be enabled by modifying ``main.py``.
 
 Integration
 -----------
diff --git a/docs/contributing.rst b/docs/contributing.rst
index 7e0957d..15f3390 100644
--- a/docs/contributing.rst
+++ b/docs/contributing.rst
@@ -10,11 +10,12 @@ Introduction
 
 Anyone can contribute to the wasp-os project. Contributions are typically made
 via github using the typical fork-and-pull-request approach. Contributors who
-do not wish to use github are also welcome to share patches using
-``git format-patch --to wasp-os@redfelineninja.org.uk`` and ``git send-email``.
-In both cases, the code will be reviewed by a project maintainer, so please
-anticipate review comments. Typically pull requests will not be merged if there
-are open questions or requests for changes that have not been acted on.
+do not wish to use github are welcome to share patches using ``git
+format-patch --to wasp-os@redfelineninja.org.uk`` and ``git send-email``. In
+both cases, the code will be reviewed by a project maintainer, so please
+anticipate review comments and requests for changes. Typically pull
+requests will not be merged if there are open questions or requests for
+changes that have not been acted on.
 
 All contributions must include a ``Signed-off-by`` tag added by the contributor
 who submits the patch or patches. The ``Signed-off-by`` tag is added at the end
@@ -68,7 +69,7 @@ easily:
 Additionally, please be aware that github will not send out automatic
 notifications to let the maintainer know that you have pushed an update to the
 pull-request. Follow up the above with a comment on the pull request thread
-saying that your contribution should be ready to go.
+saying that your contribution has been updated and is ready for another look.
 
 Code of Conduct
 ---------------
diff --git a/docs/install.rst b/docs/install.rst
index 8d0494d..1048f4a 100644
--- a/docs/install.rst
+++ b/docs/install.rst
@@ -31,9 +31,8 @@ a complete sphinx toolchain:
     sudo apt install sphinx graphviz python3-recommonmark
 
 Alternatively, if your operating system does not package some or any of
-the aforementioned Python modules that were included in the previous
-command, you can install all of them with pip instead. Make sure to
-adapt the following command appropriately:
+the above mentioned Python modules then you can install all of them
+with pip instead:
 
 .. code-block:: sh
 
@@ -48,37 +47,37 @@ tested using the `GNU-RM toolchain
 
     There are known problems with toolchains older than gcc-7.3 when
     link time optimization is enabled during the MicroPython build
-    (and LTO is enabled by default).
+    (LTO is enabled by default).
 
 Fetch the code from
-`https://github.com/daniel-thompson/wasp-os <https://github.com/daniel-thompson/wasp-os>`_ :
+`https://github.com/daniel-thompson/wasp-os <https://github.com/daniel-thompson/wasp-os>`_  and download the prerequisites:
 
 .. code-block:: sh
 
-   git clone https://github.com/daniel-thompson/wasp-os
-   cd wasp-os
-   make submodules
-   make softdevice
+    git clone https://github.com/daniel-thompson/wasp-os
+    cd wasp-os
+    make submodules
+    make softdevice
 
 To build the firmware select the command appropriate for your board from the
 list below:
 
 .. code-block:: sh
 
-   make -j `nproc` BOARD=pinetime all
-   make -j `nproc` BOARD=k9 all
-   make -j `nproc` BOARD=p8 all
+    make -j `nproc` BOARD=pinetime all
+    make -j `nproc` BOARD=k9 all
+    make -j `nproc` BOARD=p8 all
 
-To rebuild the documentation try:
+To rebuild the documentation:
 
 .. code-block:: sh
 
-   make docs
+    make docs
 
 Device Support
 --------------
 
-wasp-os can run on multiple devices and, in time, will hopefully be ported to
+Wasp-os can run on multiple devices and, in time, will hopefully be ported to
 many more.
 
 In terms of deciding which device to buy we can suggest two criteria to help.
@@ -95,9 +94,9 @@ second criteria is not technical, it is about community. The Pine64 PineTime is
 unique among the devices supported by wasp-os because it is intended that the
 watch be used to run a variety of different open source or free software
 operating systems. By manufacturing a watch with the intention that it be
-hacked every which way from Sunday then we get a bigger stronger community
+hacked every which way from Sunday then we get a bigger, stronger community
 focused on the PineTime. There is a vibrant support forum, multiple different
-OS developers (who share ideas and knowledge even if hacking on very different
+OS developers (who share ideas and knowledge even when hacking on very different
 code bases) combined with a `near complete set of hardware documentation
 <https://wiki.pine64.org/index.php/PineTime>`_.
 
@@ -110,7 +109,7 @@ only sold for short periods and may experience undocumented technical changes
 between manufacturing runs that can cause compatibility problems. This makes it
 hard for a large community to form around these devices.
 
-Thus the second criteria it to think about your own needs and abilities.  If
+Thus the second criteria it to think about your own needs and abilities. If
 you want to enjoy the social and community aspects of working together on open
 source watch development then you should look very closely at the PineTime.
 
@@ -122,7 +121,7 @@ based on an nRF52832 SoC and includes a 240x240 colour display with touch
 screen, a step counter and a heart rate sensor.
 
 wasp-os can be installed directly from the factory default operating
-system using an over-the-air update with no tools or disassembly is
+system using an over-the-air update with no tools or disassembly
 required. nRF Connect for Android can be used to install both the
 :ref:`wasp-bootloader<Bootloader nRF Connect>` and the
 :ref:`main OS image<Main OS nRF Connect>`.
@@ -132,9 +131,9 @@ required. nRF Connect for Android can be used to install both the
     The early adopter PineTime Developer Edition came pre-programmed
     with a proprietary test firmware rather than the current factory
     default OS. If you have an early adopter unit then it will appear
-    in the device list as *Y7S* and the tools needed for an OTA update
-    are differnt. DaFlasher for Android can be used to install both the
-    :ref:`wasp-bootloader<Bootloader DaFlasher>` and the
+    in the device list as *Y7S*. In this case the process needed for an
+    OTA update is different. Use DaFlasher for Android to install both
+    the :ref:`wasp-bootloader<Bootloader DaFlasher>` and the
     :ref:`main OS image<Main OS DaFlasher>`.
 
 The `developer edition <https://store.pine64.org/?product=pinetime-dev-kit>`_
@@ -152,9 +151,10 @@ provides a 240x240 colour display together with a touch screen and a
 physical button, all of which appears as a window on your host computer.
 
 The simulator has large quantities of memory and, whilst useful for
-exploring wasp-os and testing your programs are syntactically correct
+exploring wasp-os and testing your programs are syntactically correct,
 it is not a substitute for testing on real hardware. See
-:ref:`Testing on the simulator` for more details on how to use the simulator.
+:ref:`Testing on the simulator` for more details on how to use the
+simulator.
 
 To launch the simulator try:
 
@@ -162,6 +162,26 @@ To launch the simulator try:
 
     make sim
 
+Colmi P8
+~~~~~~~~
+
+The `Colmi P8 <https://www.colmi.com/products/p8-smartwatch>`_ is an almost
+square smart watch based on an nRF52832 SoC and includes a 240x240 colour
+display with touch screen, a step counter and a heart rate sensor.
+
+.. warning::
+
+    The P8 has multiple hardware revisions and the newest version (the
+    one that includes a magnetic charger) uses a different and,
+    currently, unsupported step counter module. The new models will
+    boot wasp-os successfully but the step counter application will
+    be disabled and cannot function.
+
+DaFlasher for Android can be used to install both the
+:ref:`wasp-bootloader<Bootloader DaFlasher>` and the
+:ref:`main OS image<Main OS DaFlasher>`. No tools or disassembly is
+required.
+
 Senbono K9
 ~~~~~~~~~~
 
@@ -171,7 +191,7 @@ rate sensor.
 
 The wasp-os port for Senbono K9 does not, at this point, include a driver for
 the touch screen because the protocol has not yet been reverse engineered. The
-touch screen enumerates via I2C at address 70d (or 0x46) and the interrupt can
+touch screen enumerates via I2C at address 70d (0x46) and the interrupt can
 be used to detect touch screen activity but the touch coordinates cannot be
 read from the hardware. Currently the touch screen can only act as a
 multi-function button and can be used to cycle through the quick ring and
@@ -186,22 +206,6 @@ DaFlasher for Android can be used to install both the
 :ref:`wasp-bootloader<Bootloader DaFlasher>` and the
 :ref:`main OS image<Main OS DaFlasher>`. No tools or disassembly is required.
 
-Colmi P8
-~~~~~~~~
-
-The `Colmi P8 <https://www.colmi.com/products/p8-smartwatch>`_ is an almost
-square smart watch based on an nRF52832 SoC and includes a 240x240 colour
-display with touch screen, a step counter and a heart rate sensor.
-
-The P8 has multiple hardware revisions and the newest version (the one that
-includes a magnetic charger) uses a different and, currently, unsupported step
-counter module. The new models will boot wasp-os successfully but the step
-counter application will not be included.
-
-DaFlasher for Android can be used to install both the
-:ref:`wasp-bootloader<Bootloader DaFlasher>` and the
-:ref:`main OS image<Main OS DaFlasher>`. No tools or disassembly is required.
-
 Installing wasp-bootloader
 --------------------------
 
@@ -213,6 +217,9 @@ nRF Connect for Android
 For Pine64 PineTime devices running Infinitime then nRF Connect for Android
 can be used to install wasp-bootloader:
 
+* Ensure the watch is fully charged before attempting to install the
+  wasp-bootloader. Running out of power during this process can brick
+  sealed devices.
 * Copy ``reloader-mcuboot.zip`` (see :ref:`Building wasp-os from source`) to
   your Android device and download
   `nRF Connect <https://play.google.com/store/apps/details?id=no.nordicsemi.android.mcp>`_
@@ -237,9 +244,10 @@ can be used to install wasp-bootloader:
 
 .. note::
 
-    It you want to restore the PineTime factory firmware then you can
-    use nRF Connect to do this. Use nRF Connect to send
-    ``reloader-factory.zip`` to the wasp-bootloader (called *PineDFU*).
+    If you want to restore the PineTime factory firmware then you can
+    use nRF Connect to do this. Perform a long press reset and then
+    use nRF Connect to send ``reloader-factory.zip`` to the *PineDFU*
+    device.
 
 .. _Bootloader DaFlasher:
 
@@ -248,6 +256,9 @@ DaFlasher for Android
 
 To install the bootloader using DaFlasher for Android:
 
+* Ensure the watch is fully charged before attempting to install the
+  wasp-bootloader. Running out of power during this process can brick
+  sealed devices.
 * Download and install
   `DaFlasher <https://play.google.com/store/apps/details?id=com.atcnetz.paatc.patc>`_
   and copy the DaFlasher bootloaders to your Android device. You will need
@@ -377,6 +388,8 @@ To install the main firmware from a GNU/Linux workstation:
   :ref:`Building wasp-os from source`) to the device. For example:
   ``tools/ota-dfu/dfu.py -z micropython.zip -a A0:B1:C2:D3:E3:F5 --legacy``
 
+.. _Troubleshooting:
+
 Troubleshooting
 ---------------
 
diff --git a/docs/license.rst b/docs/license.rst
index 47c585a..a48d128 100644
--- a/docs/license.rst
+++ b/docs/license.rst
@@ -18,8 +18,8 @@ the MicroPython distribution, are licensed under under different open
 source licenses. The licensing for these components is clearly
 indicated and reinforced by the directory and sub-module structure.
 
-Additionally binary releases of wasp-os include the Nordic Softdevice
-which is licensed under the 5-clause Nordic license.
+Additionally binary releases of wasp-os include a binary copy of the
+Nordic Softdevice which is licensed under the 5-clause Nordic license.
 
 .. toctree::
    gnu-lgpl-v3.0.rst
diff --git a/wasp/boards/sphinx/icons.py b/wasp/boards/sphinx/icons.py
index 5dc9f0a..272bd20 100644
--- a/wasp/boards/sphinx/icons.py
+++ b/wasp/boards/sphinx/icons.py
@@ -5,6 +5,7 @@ battery = 'Default battery icon'
 bomb = 'Small bomb icon'
 app = 'Default application icon'
 clock = 'Default digital clock icon'
+headset = 'Default music player icon'
 settings = 'Default settings icon'
 torch = 'Default torch or flashlight icon'
 up_arrow = 'Small (16x9) up arrow'