Particle based accelerometer

What is claimed is: 1 . A sensor for sensing acceleration forces applied to a device on which said sensor is mounted, the sensor comprising: a first sealed container containing a first liquid; a second sealed container containing a second liquid, said first and second sealed contained having two common junction points such that, at each junction point, a boundary exists between said first and second liquids; two indicators, each indicator being located at one of said two common junction points between said first and said second sealed containers; a tracking subsystem for tracking positions of said indicators as at least a portion of said indicators move with said boundary; wherein boundaries between said first and second liquids are affected by acceleration forces applied to said device such that said boundaries move when an acceleration is applied to said device, an amount of movement of said boundary being dependent on an amount of acceleration force being applied to said device; said indicators are similarly affected by said movement of said boundaries such that an effect on said indicators by said movement is dependent on said amount of acceleration applied to said device. 2 . The sensor according to claim 1 , wherein said tracking subsystem is an imaging tracking subsystem that tracks a position of said at least said portion of said indicators. 3 . The sensor according to claim 1 , wherein at least one of said two indicators is at least one particle whose position is trackable by said tracking subsystem. 4 . The sensor according to claim 1 , wherein at least one of said two indicators is a beam-like element and wherein a portion of said element deflects whenever said boundary moves, a deflection of said element being proportional to said acceleration forces applied to said device. 5 . The sensor according to claim 1 , wherein said first liquid and said second liquid are differently colored liquids that are immiscible in one another. 6 . The sensor according to claim 3 , wherein said at least one particle is neutrally buoyant in both of said first and said second liquids. 7 . The sensor according to claim 1 , wherein said tracking subsystem comprises a data processing module for calculating acceleration forces based on said amount of movement of said boundaries as determined by an amount of movement of said portion of said indicators. 8 . An accelerometer for determining acceleration forces applied to a device on which said accelerometer is mounted, the accelerometer comprising: a first subsystem for measuring acceleration forces applied on a first plane; a second subsystem for measuring acceleration forces applied on a second plane, said first plane and said second plane being orthogonal to one another; wherein each of said first subsystem and said second subsystem comprises: a first sealed container containing a first liquid; a second sealed container containing a second liquid, said first and second sealed contained having two common junction points such that, at each junction point, a boundary exists between said first and second liquids; two indicators, each indicator being located at one of said two common junction points between said first and said second sealed containers; a tracking subsystem for tracking positions of said indicators as at least a portion of said indicators move with said boundary; and wherein for each subsystem, boundaries between said first and second liquids are affected by acceleration forces applied to said subsystem such that said boundaries move when an acceleration is applied to said subsystem, an amount of movement of said boundary being dependent on an amount of acceleration force being applied to said subsystem; said indicators are similarly affected by said movement of said boundaries such that an effect on said indicators by said movement is dependent on said amount of acceleration applied to said subsystem. 9 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, said tracking subsystem is an imaging tracking subsystem that tracks a position of said at least said portion of said indicators. 10 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, at least one of said two indicators is at least one particle whose position is trackable by said tracking subsystem. 11 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, at least one of said two indicators is a beam-like element and wherein a portion of said element deflects whenever said boundary moves, a deflection of said element being proportional to said acceleration forces applied to said subsystem. 12 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, said first liquid and said second liquid are differently colored liquids that are immiscible in one another. 13 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, said at least one particle is neutrally buoyant in both of said first and said second liquids. 14 . The accelerometer according to claim 8 , wherein for at least one of said first subsystem and said second subsystem, said tracking subsystem comprises a data processing module for calculating acceleration forces based on said amount of movement of said boundaries as determined by an amount of movement of said portion of said indicators. 15 . A method for determining acceleration forces applied to an accelerometer that comprises two containers having at least one common junction point, each of said two containers containing first and second liquids such that, at each of said junction points, a boundary exists between said first and second liquids, said accelerometer further comprising at least one indicator, each of said at least one indicator being located at one of said at least one common junction point, the method comprising: a) obtaining a first image of said at least one indicator when said at least one indicator is at rest; b) obtaining at least one second image of said at least one indicator when said accelerometer is subjected to acceleration; c) determining an amount of change for said at least one indicator between said first image and said at least one second image; d) determining said acceleration forces based on said amount of change for said at least one indicator. 16 . The method according to claim 15 , wherein said at least one indicator is a beam-like element. 17 . The method according to claim 16 , wherein said amount of change for said at least one indicator is an amount of deflection of said beam-like element. 18 . The method according to claim 15 , wherein said at least one indicator is a marker that is buoyant in said first and second liquids. 19 . The method according to claim 18 , wherein said amount of change for said at least one indicator is an amount of displacement of said at least one indicator between a first position in said first image and at least one second position in said at least one second image. 20 . The method according to claim 17 , further comprising determining said acceleration forces based on said amount of deflection. 21 . The method according to claim 19 , further comprising determining said acceleration forces based on said amount of displacement.