diff --git a/doc/shared/en-US/pacemaker-intro.txt b/doc/shared/en-US/pacemaker-intro.txt
index 4a85caf804..a457bab1d2 100644
--- a/doc/shared/en-US/pacemaker-intro.txt
+++ b/doc/shared/en-US/pacemaker-intro.txt
@@ -1,146 +1,147 @@
 
 == What Is 'Pacemaker'? ==
 
 Pacemaker is a 'cluster resource manager'.
 
 It achieves maximum availability for your cluster services
-(aka. 'resources') by detecting and recovering from node- and
+(a.k.a. 'resources') by detecting and recovering from node- and
 resource-level failures by making use of the messaging and membership
 capabilities provided by your preferred cluster infrastructure (either
 http://www.corosync.org/[Corosync] or
 http://linux-ha.org/wiki/Heartbeat[Heartbeat]).
 
 Pacemaker's key features include:
 
  * Detection and recovery of node and service-level failures
  * Storage agnostic, no requirement for shared storage
  * Resource agnostic, anything that can be scripted can be clustered
- * Supports 'fencing' (aka. 'STONITH') for ensuring data integrity
+ * Supports 'fencing' (also known under 'STONITH' acronym) for ensuring
+   data integrity
  * Supports large and small clusters
  * Supports both quorate and resource-driven clusters
  * Supports practically any redundancy configuration
  * Automatically replicated configuration that can be updated
    from any node
  * Ability to specify cluster-wide service ordering,
    colocation and anti-colocation
  * Support for advanced service types
  ** Clones: for services which need to be active on multiple nodes
  ** Multi-state: for services with multiple modes
-    (eg. master/slave, primary/secondary)
+    (e.g. master/slave, primary/secondary)
  * Unified, scriptable cluster management tools
 
 == Pacemaker Architecture ==
 
 At the highest level, the cluster is made up of three pieces:
 
  * *Non-cluster-aware components*. These pieces
    include the resources themselves; scripts that start, stop and
    monitor them; and a local daemon that masks the differences
    between the different standards these scripts implement.
 
  * *Resource management*. Pacemaker provides the brain that processes
    and reacts to events regarding the cluster.  These events include
    nodes joining or leaving the cluster; resource events caused by
    failures, maintenance and scheduled activities; and other
    administrative actions. Pacemaker will compute the ideal state of
    the cluster and plot a path to achieve it after any of these
    events. This may include moving resources, stopping nodes and even
    forcing them offline with remote power switches.
 
  * *Low-level infrastructure*. Projects like 'Corosync', 'CMAN' and
    'Heartbeat' provide reliable messaging, membership and quorum
    information about the cluster.
 
 When combined with Corosync, Pacemaker also supports popular open
 source cluster filesystems.{empty}footnote:[
   Even though Pacemaker also supports Heartbeat, the filesystems need to
   use the stack for messaging and membership, and Corosync seems to be
   what they're standardizing on.  Technically, it would be possible for
   them to support Heartbeat as well, but there seems little interest
   in this.
 ]
 
 Due to past standardization within the cluster filesystem community,
 cluster filesystems make use of a common 'distributed lock manager',
 which makes use of Corosync for its messaging and membership
 capabilities (which nodes are up/down) and Pacemaker for fencing
 services.
 
 .The Pacemaker Stack
 image::images/pcmk-stack.png["The Pacemaker stack",width="10cm",height="7.5cm",align="center"]
 
 === Internal Components ===
 
 Pacemaker itself is composed of five key components:
 
  * 'Cluster Information Base' ('CIB')
  * 'Cluster Resource Management daemon' ('CRMd')
  * 'Local Resource Management daemon' ('LRMd')
  * 'Policy Engine' ('PEngine' or 'PE')
  * Fencing daemon ('STONITHd')
 
 .Internal Components
 image::images/pcmk-internals.png["Subsystems of a Pacemaker cluster",align="center",scaledwidth="65%"]
 
 The CIB uses XML to represent both the cluster's configuration and
 current state of all resources in the cluster. The contents of the CIB
 are automatically kept in sync across the entire cluster and are used by
 the PEngine to compute the ideal state of the cluster and how it should
 be achieved.
 
 This list of instructions is then fed to the 'Designated Controller'
 ('DC').  Pacemaker centralizes all cluster decision making by electing
 one of the CRMd instances to act as a master. Should the elected CRMd
 process (or the node it is on) fail, a new one is quickly established.
 
 The DC carries out the PEngine's instructions in the required order by
 passing them to either the Local Resource Management daemon (LRMd) or
 CRMd peers on other nodes via the cluster messaging infrastructure
 (which in turn passes them on to their LRMd process).
 
 The peer nodes all report the results of their operations back to the DC
 and, based on the expected and actual results, will either execute any
 actions that needed to wait for the previous one to complete, or abort
 processing and ask the PEngine to recalculate the ideal cluster state
 based on the unexpected results.
 
 In some cases, it may be necessary to power off nodes in order to
 protect shared data or complete resource recovery. For this, Pacemaker
 comes with STONITHd. 
 
 STONITH is an acronym for 'Shoot-The-Other-Node-In-The-Head' and is
 usually implemented with a remote power switch.
 
 In Pacemaker, STONITH devices are modeled as resources (and configured
 in the CIB) to enable them to be easily monitored for failure, however
 STONITHd takes care of understanding the STONITH topology such that its
 clients simply request a node be fenced, and it does the rest.
 
 == Types of Pacemaker Clusters ==
 
 Pacemaker makes no assumptions about your environment. This allows it
 to support practically any
 http://en.wikipedia.org/wiki/High-availability_cluster#Node_configurations[redundancy
 configuration] including 'Active/Active', 'Active/Passive', 'N+1',
 'N+M', 'N-to-1' and 'N-to-N'.
 
 .Active/Passive Redundancy
 image::images/pcmk-active-passive.png["Active/Passive Redundancy",width="10cm",height="7.5cm",align="center"]
 
 Two-node Active/Passive clusters using Pacemaker and 'DRBD' are
 a cost-effective solution for many High Availability situations.
 
 .Shared Failover
 image::images/pcmk-shared-failover.png["Shared Failover",width="10cm",height="7.5cm",align="center"]
 
 By supporting many nodes, Pacemaker can dramatically reduce hardware
 costs by allowing several active/passive clusters to be combined and
 share a common backup node.
 
 .N to N Redundancy
 image::images/pcmk-active-active.png["N to N Redundancy",width="10cm",height="7.5cm",align="center"]
 
 When shared storage is available, every node can potentially be used for
 failover.  Pacemaker can even run multiple copies of services to spread
 out the workload.