/TH/ACCEL

Format

(1)	(2)	(3)	(4)	(5)	(6)	(7)	(8)	(9)	(10)
/TH/ACCEL/`thgroup_ID`
`thgroup_name`
`var_ID`₁	`var_ID`₂	`var_ID`₃	`var_ID`₄	`var_ID`₅	`var_ID`₆	`var_ID`₇	`var_ID`₈	`var_ID`₉	`var_ID`₁₀
`Obj_ID`₁	`Obj_ID`₂	`Obj_ID`₃	`Obj_ID`₄	`Obj_ID`₅	`Obj_ID`₆	`Obj_ID`₇	`Obj_ID`₈	`Obj_ID`₉	`Obj_ID`₁₀

Definitions

Field	Contents	SI Unit Example
`thgroup_ID`	`TH` group identifier (Integer, maximum 10 digits)
`thgroup_name`	`TH` group name (Character, maximum 100 characters)
`var_ID`₁, ...`n`	Variables saved for `TH` (see table below) (Character, maximum 8 characters)
`Obj_ID`₁, ...`n`	Identifiers of the objects to be saved (Integer)

TH Output Keyword & Variables

Keyword	Object Saved	Variables
`ACCEL`	`Accelerometer`	`AX, AY, AZ, WX, WY, WZ`

Table of Available Variables - Part 2

Keyword	Variable Group	Saved TH Variables
`ACCEL`	`DEF W`	`AX, AY, AZ, WX, WY, WZ`

Output for Accelerometer

AX: acceleration in direction X
AY: acceleration in direction Y
AZ: acceleration in direction Z
WX: integral of acceleration in direction X
WY: integral of acceleration in direction Y
WZ: integral of acceleration in direction Z
Let $γ_{g}$ the nodal acceleration vector with laboratory expressed in the global skew system, $γ_{s}$ the nodal acceleration vector with laboratory projected onto the moving skew.

Let $ν_{g}$ the nodal velocity vector with laboratory expressed in the global skew system, $ν_{s}$ the nodal velocity vector with laboratory projected onto the moving skew.

Let

R (t)

the orientation matrix of the skew at time t, so that: (1)

γ_{s} = R (t) \cdot γ_{g}

(2)

v_{s} = R (t) \cdot v_{g}

Derivating

ν_{s}

versus time leads to:(3)

\frac{d v_{s}}{d t} = \frac{d R}{d t} v_{g} + R \frac{d v_{g}}{d t} = \frac{d R}{d t} v_{g} + R γ_{g} = \frac{d R}{d t} v_{g} + γ_{s}

This shows that derivating the nodal velocity with laboratory projected onto the moving skew, $ν_{s}$ does not give as a result the nodal acceleration with laboratory projected onto the moving skew, $γ_{s}$ .

The vector WX, WY, and WZ available for output in the accelerometer is:(4)

w = \int_{0}^{t} γ_{s} (u) d u

Derivating to this output will give a value of $γ_{s}$ nodal acceleration with laboratory projected onto the moving skew, the integration-derivation acting as another filter other than the 4-pole Butterworth, which is used in the accelerometer and computes the filtered accelerations AX, AY, and AZ.

Comments

Available names are listed in the two tables above.
In the first table, TH-variables are listed. If a TH-variable is requested, this variable is written.

In the second table, variable groups are listed. If a variable group is requested, all the associated TH-variables are written at once.