Abstract—Presented in this paper is an actuator concept, 
called a Parallel Force/Velocity Actuator (PFVA), that 
combines two fundamentally distinct actuators (one using low 
gear reduction or even direct drive, which we will call a Force 
Actuator (FA) and the other with a high reduction gear train 
that we will refer to as a Velocity Actuator (VA)). The objective 
of this work is to evaluate the effect of the relative scale factor, 
RSF, (ratio of gear reductions) between these inputs on their 
dynamic coupling. We conceptually describe a Parallel 
Force/Velocity Actuator (PFVA) based on a Dual-Input-Single-
Output (DISO) epicyclic gear train. We then present an 
analytical formulation for the variation of the dynamic coupling 
term w.r.t. RSF. Conclusions from this formulation are 
illustrated through a numerical example involving a 1-DOF 
four-bar linkage. It is shown, both analytically and numerically, 
that as we increase the RSF, the two inputs to the PFVA are 
decoupled w.r.t. the inertia torques. This understanding can 
serve as an important design guideline for PFVAs. The paper 
also presents two limitations of this study and suggests future 
work based on these caveats.  
I. INTRODUCTION 
Dexterous manipulation applications require very smooth 
motion planning and intricate force-profile management. The 
most challenging tasks are the ones in which force and 
motion have to be managed in the same direction, like 
deburring. Dexterous tasks can, in the limit, be classified into 
two mutually exclusive functional regimes, namely, force-
controlled and velocity controlled. In purely force-controlled 
tasks, the objective is to achieve a desired interaction force 
(velocity management being secondary) and in purely 
velocity-controlled tasks, the goal is to adhere to a reference 
motion plan (force control being secondary). 
The Electro-Mechanical Actuators (EMA) that drive 
intelligent mechanical systems (like robots) can also be 
classified into “ideal” Force Actuators (FA) and “ideal” 
Velocity Actuators (VA). The reduction used in their gear 
trains characterizes them as FA or VA. A high reduction gear 
ratio (such as 150:1) makes the actuator behave like a 
velocity generator or VA in that it can manage a commanded 
velocity while resisting force disturbances with minimal 
impact on the commanded velocity. On the other hand, an 
EMA with a low reduction gear ratio (such as a direct drive 
actuator) acts like an ideal force generator or a FA. In other 
words, an FA can maintain a reference force while reacting 
 
 
to velocity disturbances. These inverse characteristics arise 
due to the fact that force and velocity are power conjugate 
variables. 
In this work, we propose an approach that combines an FA 
and a VA within the same design in parallel. Further we 
focus our attention here on a study of the effect of relative 
scale factor between the two inputs, on the dynamic coupling 
between them. This study is important because the dynamic 
(or inertial) coupling between the inputs dictates how much 
each of them gets disturbed by the variations in the inertia at 
the system output. A clear analytical and physical 
understanding of this coupling term will thus be a significant 
step towards the design of such systems.  
The paper is organized to present a review of the pertinent 
literature first. We then present the concept of the Parallel 
Force/Velocity 
Actuator 
(PFVA) 
and 
its 
analysis. 
Subsequently, we present an analytical study of the dynamic 
coupling term as a function of the relative scale factor 
between the two inputs to the PFVA. A numerical example is 
included to illustrate the conclusions from the analytical 
formulation. The paper concludes with a discussion of the 
results and two suggestions for future work.   
II. LITERATURE REVIEW 
The fundamental issue in this paper is to characterize the 
dynamic coupling between the two inputs in a Parallel 
Force/Velocity Actuator (PFVA) [15] which will then serve 
as a design guideline. The objective of the PFVA is to obtain 
a variety of dynamic responses at the system’s output, from 
the highly stiff ‘pure velocity controlled response’ to the 
more forgiving ‘pure force controlled response’. In this 
section we will review relevant actuation concepts that were 
motivated by similar goals.  
The significance of the actuator and its properties in 
determining the limits of performance of a robotic system 
have been recognized earlier by Tesar [1] and Hollerbach et 
al. [2]. The dependence of system performance on actuator 
characteristics (especially bandwidth) has been studied in the 
past by Eppinger and Seering [3] and Hollerbach et al. [2]. 
To improve force-controlled performance, research at the 
MIT Leg Lab purposely included series compliance between 
the actuator and the load (Series Elastic Actuation, SEA) to 
reduce impact loads [4]. Joint level torque-control was 
proposed by Vischer and Khatib [5] to reduce the non-linear 
Study of the Dynamic Coupling Term (µ) in Parallel Force/Velocity 
Actuated Systems 
Dinesh Rabindran and Delbert Tesar 
Robotics Research Group, Department of Mechanical Engineering 
University of Texas at Austin 
 
2 
effects in actuators. This method can actively change the 
response of an actuator (very stiff or forgiving) depending on 
the task; but for frequencies beyond the joint torque control 
bandwidth, the response is governed by its structural 
compliance. Joint torque control is also used in the operation 
of the DLR-III lightweight manipulator arm [6]. A new 
actuation concept, called Distributed Macro-Mini (DM2) 
Actuator, for human-centered robotic systems, was proposed 
at the Stanford Robotics Lab [7]. This research was driven 
by the need to design safer as well as better performing 
robots. The central idea of DM2 was to partition input torque 
generation into high frequency and low frequency 
components that sum in parallel and are appropriately 
located at the joint and the base of the manipulator. At the 
University of Texas, the actuation effort has been toward 
maximizing the number of choices (in the force and motion 
domains) available within the actuator. This includes dual-
level control for fault-tolerance [8] and layered control [9]. 
The Parallel Coupled Micro-Macro Actuator (PaCMMA) 
from MIT [10] was a concept similar to layered control [9]. 
The objective of PaCMMA, an in-parallel design, was to 
improve the force resolution and closed-loop force control 
bandwidth; however it has packaging issues due to its 
complexity. An actuation mechanism was proposed by Kim 
et al. [11] at Korea University based on a planetary gear 
train. This is a Dual Actuator Unit (DAU) that is driven by 
two sub-systems, a “positioning actuator” and a “stiffness 
modulator”. The DAU concept bears resemblance to the 
Force/Motion Actuator1 proposed earlier by Tesar [12]. The 
DAU operates such that the “stiffness modulator” biases the 
position of the “positioning actuator” when a collision is 
detected. It is well-packaged in a protoype; however, Kim et 
al. [11] have not investigated any of the operational issues 
associated with multi-input gear trains (for example, the 
dynamic influence of one input on the other). Another 
actuation paradigm based on a Continuously Variable 
Transmission (CVT) was proposed by Faulring et al. [13] at 
Northwestern University which they called Cobotics. The 
goal of this CVT approach was to improve power efficiency.  
The premise of the PFVA concept is that we could 
dynamically “mix” the contributions of a pair of low-
reduction (Force Actuator, FA) and high-reduction (Velocity 
Actuator, VA) actuators in-parallel to obtain a variety of 
responses at the system’s output. This concept of Parallel 
Force/Velocity actuation revolves around the fact that the 
gear-ratio is a significant property of the actuator [14]. In 
this paper, however, we restrict our study to the issue of 
dynamic coupling between the inputs to the PFVA. In the 
next section we will present the concept of a Parallel 
Force/Velocity Actuator (PFVA) and in subsequent sections 
we will lay out the analytics required to characterize the 
dynamic coupling term between the constituent sub-systems, 
namely, the FA and VA. 
 
1 Conceptual origin of the PFVA (proposed in this paper) 
III. PARALLEL FORCE/VELOCITY ACTUATION PRINCIPLE 
In this section we will present the Parallel Force/Velocity 
Actuation (PFVA) concept. Recognizing that the gear ratio 
of an actuator is a significant property that influences the 
dynamic response at the output of the system, we will 
classify EMAs into two mutually exclusive classes based on 
their transmission ratios (Fig 1), namely the ideal “Force 
Actuator” (FA) and the ideal “Velocity Actuator” (VA). The 
FA is a low-reduction actuator (10-15 to 1 or even direct 
drive) that is ideal for tasks in which the output force is 
being controlled while velocity disturbances are being 
tolerated. In other words, a FA is a perfect force/torque 
source. On the other hand, the VA is a high-reduction 
actuator (100-150 to 1) that performs well in applications 
where the velocity needs to be controlled precisely while 
rejecting force disturbances. A VA is an ideal velocity 
source. The PFVA concept combines the above two classes 
of actuators in one Dual Input Single Output (DISO) design 
using an epicyclic gear train. 
Force Actuator (FA)
High Velocity, Low Torque
Force Control
Velocity Disturbance Rejection
High Responsiveness
Low Effective  Inertia
Gear Ratios
Direct Drive
(1 to 1)
High Reduction
(100-150 to 1)
Spectrum of EM Actuators
Velocity Actuator (VA)
High Torque, Low Velocity
Velocity Control
Force Disturbance Rejection
Low Responsiveness
High Effective  Inertia
 
Fig 1. Spectrum of EMAs based on Gear Reduction 
 
A. Parallel Force/Velocity Actuation – Analysis 
In a Parallel Force/Velocity Actuator (PFVA), we 
combine a Force Actuator and a Velocity Actuator in parallel 
using a 2-DOF epicyclic gear train. In Fig 2 is shown the 
configuration of the epicyclic gear train to realize our 
objective of incorporating fundamentally distinct force and 
motion priorities within the same actuator. There are two 
inputs to the epicyclic gear train. As shown in the schematic 
(Fig 2), the prime-mover of the FA drives the sun-gear shaft 
and that of the VA drives the carrier. The output is the ring 
gear. In keeping with our nomenclature for the ideal 
 
3 
actuators, the prime-movers for the FA and VA will 
respectively be called the force input (or force sub-system, 
FSS) and velocity input (or velocity sub-system, VSS). The 
properties of a Parallel Force/Velocity Actuator are listed in 
Table I.  
o
o
τ ω
v
v
τ ω
f
f
τ ω
 
Fig 2. Schematic of a Dual Input Single Output Planetary Gear Train.  
 
TABLE I 
PARALLEL FORCE/VELOCITY ACTUATOR PROPERTIES 
Symbol 
Quantity 
o
ω  
Output Angular Velocity of the PFVA 
v
ω  
Angular Velocity of the Velocity Input in PFVA 
f
ω
 
Angular Velocity of the Force Input in PFVA 
o
τ
 
Output Torque of the PFVA 
vτ  
Torque at the Velocity Input in PFVA 
f
τ
 
Torque at the Force Input in PFVA 
f
R
 
Gear Reduction for Force Side 
v
R  
Gear Reduction for Velocity Side 
ρ  
Relative scale factor Between Sub-Systems,
f
v
R
R
 
 
In the following analysis we will use some results from 
Muller [16]. The output velocity of the PFVA is a linear 
combination of the input velocities with scaling dependent 
on the gear ratios of their respective force paths. We may 
express the velocity mapping as a velocity summation: 
o
v
v
f
f
R
R
ω
ω
ω
=
+
 
(1) 
Now, considering the conservation of power (if we assume 
no power loss due to inefficiency),  
o
o
v
v
f
f
τ ω
τ ω
τ ω
=
+
 
(2) 
 
Using Eqns. (1) and (2) it can be shown that the torque 
mapping between the inputs and the output of the PFVA is as 
follows:  
f
v
o
v
f
R
R
τ
τ
τ =
=
 
(3) 
 
The above relation may be re-written in vector form as 
follows: 
v
v
o
f
f
R
R
τ
τ
τ




=








 
(4) 
 
It is a property of the epicyclic gear train [16] shown in Fig 
2, that: 
1
v
f
R
R
+
=
 
(5) 
 
Let us define the Relative scale factor (ρ) between the inputs 
as follows:  
f
v
R
R
ρ =
 
(6) 
 
Then we may use the relation in Eqn. (5) to re-write the 
individual gear reductions as follows: 
1
1
v
R
ρ
=
+
 
(7) 
 
1
f
R
ρ
ρ
=
+
 
(8) 
 
From Eqns.(7) and (8), we recognize that 
1
ρ =
 is a 
singularity for the epicyclic gear train. The physical meaning 
of this scenario is that the whole system rotates with one 
single velocity and behaves like a Single Input Single Output 
(SISO) transmission system with the gear ratio equal to 
unity. 
IV. STUDY OF DYNAMIC COUPLING TERM ( µ ) 
In this section we will present our study of the dynamic 
coupling term (µ) in the input reflected inertia matrix of a 1-
DOF PFVA actuated system. This term (µ) is an important 
design metric for the DISO Parallel Force/Velocity Actuator 
(PFVA). Browning and Tesar [18] recognized the 
importance of this coupling term as a performance criterion 
for operating n-DOF manipulator systems. In the following 
derivation, however, we will consider a single-link 
equivalent of a non-linear single-DOF mechanism (Fig 3). 
The joint displacement variable is θ, and those for the two 
inputs are φV and φF (respectively for the velocity subsystem 
and the force-subsystem). Transformation of the nonlinear 
dynamics of a complex system to the single-link equivalent is 
discussed in [19]. As will become evident from the following 
derivation, the fundamental characteristic of µ is independent 
of the reflected inertia at the joint (output of the PFVA). It is 
a function only of the Relative Scale Factor (RSF) (or ρ). 
The velocity transformation from the PFVA input space to 
the joint space may be written in matrix form as follows.  
v
v
f
f
R
R
θ
φ
φ
θ
φ






=
=










G
φ








 
(9) 
 
4 
Here, 
θ
φ




G
 represents a (constant) matrix of kinematic 
influence coefficients (Refer [17]) consisting of the velocity 
ratios for the two inputs to the output. If 
*
θθ
I
is the joint 
reflected inertia of a 1-DOF mechanism that is driven by the 
PFVA, then we can reflect this inertia to the two inputs (
*
φφ
I
) 
of the PFVA, namely the VA and FA as follows: 
*
*
T
M
I
θ
θ
φφ
φ
θθ
φ




=
+ 



I
I
G
G
 
(10) 
 
VA/VSS Input
FA/FSS Input
Output
θ
( )
*
K
θ
( )
*
C
θ
*
θθ
I
 
Fig 3. Single link equivalent of a complex 1-DOF nonlinear mechanism. 
Refer [19] for details. 
 
Here,  
0
0
Mv
M
Mf
I
I


= 



I
 is a diagonal matrix of the rotor 
inertias of the motors driving the two inputs. Recognizing 
from Eqns. (7) and (8) that,  
1
1
1
θ
φ
ρ
ρ
ρ



= 



+
+


G
 
(11) 
 
it can be shown that; 
(
)
(
)
(
)
(
)
*
*
2
2
*
2
*
*
2
2
1
1
1
1
1
Mv
Mf
I
I
I
I
I
I
θθ
θθ
φφ
θθ
θθ
ρ
ρ
ρ
ρ
ρ
ρ
ρ


+


+
+


= 

+


+
+




I
 
(12) 
 
We now have an explicit formula for the dynamic 
coupling term as a function of the Relative Scale Factor2 [µ 
(ρ)]: 
(
)
*
2
1
Iθθ
ρ
µ
ρ
=
+
 
(13) 
 
To understand the sensitivity of the dynamic coupling (µ) 
to design changes in the RSF (ρ), we take differentials on 
both sides of Eqn. (13).   
 
2 RSF – Relative Scale Factor (ρ) 
(
)
*
3
1
1
Iθθ
ρ
µ
ρ
ρ


−
∆
=
∆


+




 
(14) 
 
The relations developed in Eqns. (13) and (14) have been 
plotted in Fig 4. A limit analysis can be done on Eqns. (13) 
and (14) to recognize that as ρ→∞, µ→0 and (∆µ/∆ρ)→0. 
This is important design knowledge and can be used as a 
design rule of thumb for PFVA actuated mechanisms.  
 
Fig 4. Variation of dynamic coupling term (µ) and its derivative w.r.t. the 
Relative Scale Factor (RSF or ρ). As ρ→∞, µ→0 and (∆µ/∆ρ)→0. 
*Iθθ is 
assumed to be unity in this plot.   
 
 A limit analysis similar to the one suggested above can be 
performed on the reflected inertia term, 
*
φφ
I
, to result in Eqn. 
(15).  
*
*
0
lim
0
Mv
Mf
I
I
I
φφ
ρ
θθ
→∞


= 

+


I
 
(15) 
 
In such a design configuration (ρ→∞), the two input systems 
are virtually decoupled w.r.t. reflected inertias. This can be 
recognized from the diagonal structure of the matrix 
*
lim
φφ
ρ→∞I
.  
A. Physical Meaning of µ  for Designer 
In the previous section we have presented an analytical 
framework that can serve as a design guideline in the 
consideration of reflected inertias for PFVA driven systems. 
Having formulated the analytics, an important question we 
wish to ask is: what is the practical significance of this 
result? 
To answer this question, we will consider the inertia 
torque demands on the two sub-systems of a PFVA using the 
inverse dynamics formulation for a 1-DOF single-link 
equivalent mechanism (as depicted in Fig 3).  This is 
presented in Eqn. (16). As our focus is on dynamic coupling, 
the non-inertial torque demands (viz. centripetal/Coriolis 
terms, gravity, and static loads) are not included.  
 
5 
(
)
(
)
(
)
(
)
*
*
2
2
2
*
*
2
2
1
1
1
1
1
I
v
Mv
v
f
I
f
v
Mf
f
I
I
I
I
I
I
θθ
θθ
θθ
θθ
ρ
τ
φ
φ
ρ
ρ
ρ
ρ
τ
φ
φ
ρ
ρ




=
+
+




+
+












=
+
+




+
+




















 
(16) 
 
Now, we will perform a limit analysis on this set of 
dynamic equations, based on our findings from Eqn. (15), to 
obtain Eqn. (17).  
[
]
[ ]
[ ]
*
lim
0
lim
0
I
v
Mv
v
f
I
f
v
Mf
f
I
I
I
ρ
θθ
ρ
τ
φ
φ
τ
φ
φ
→∞
→∞
=
+


=
+
+













  
(17) 
 
With regard to reflected inertia, Eqn. (17) suggests that, 
the force subsystem manages almost all of the output inertia 
while the velocity subsystem does not see any reflected 
inertia. This is entirely desirable from a design point of view 
because a design configuration with a relatively large value 
of ρ decouples the two input subsystems (FA and VA) w.r.t. 
inertias. However, there is a practical limitation to achieving 
this, as described in Section. VII.  
V. NUMERICAL EXAMPLE 
The objective of this simulation was to illustrate the 
analytical formulation presented in this paper, i.e., the effect 
of relative scale factor (ρ) between the force and velocity 
inputs of the PFVA on their dynamic coupling (µ). There are 
two specific issues we intend to illustrate using this 
simulation; (a) Which input predominantly feels the inertia?,  
and (b) How does the dynamic coupling term (off-diagonal 
term) change with ρ? For this simulation, a crank-slider 
mechanism with a PFVA input was used. The simulation was 
set up such that the prescribed motion would have 
appreciable dynamics. A trapezoidal motion plan (constant 
acceleration – constant velocity – constant deceleration) was 
imposed on the slider (Fig 5). The initial and final positions 
of the slider were 0.3263m and 0.5873m, respectively. The 
maximum acceleration and velocity used for this run were, 
respectively, 0.3 ms-1 and 1 ms-2. The relative scaling ratio, 
ρ, between the force prime-mover and the velocity prime-
mover was varied from 5.0 (Relatively Coupled Inputs) to 
15.0 (Relatively Uncoupled Inputs).  
The numerical result is shown in Fig 5. As shown in this 
figure, the magnitude of the dynamic coupling term 
decreases as the relative scale factor increases. Physically, 
this may be interpreted as follows. If the two sub-systems 
driving the two inputs of the PFVA have comparable gear 
ratios, then a predominant part of the inertia torque of each 
sub-system is used to fight the acceleration of the other sub-
system. Hence, as a design guideline, if the inputs to a PFVA 
are near-ideal “force” and “velocity” actuators, then this 
(dynamic) coupling is negligible. 
 
 
 
Fig 5. The Effect of Relative scale factor (ρ) on Dynamic 
Coupling (µ) between the Input Sub-Systems during a 
Trapezoidal Motion Profile. 
VI. DISCUSSION 
In this paper we have presented the concept of a Parallel 
Force/Velocity Actuator (PFVA) that is based on a Dual 
Input Single Output (DISO) epicyclic gear train. One of the 
force paths in this gear train is a high-gear-ratio path and the 
other one is a low-gear-ratio path. The former input (on the 
carrier of the gear train), called a “Velocity” input, is not 
backdriveable and is capable of managing the output velocity 
without being disturbed by external forces. The latter sub-
system (connected to the sun of the planetary gear train), 
called a “Force” input, is a near-direct drive input that is 
highly responsive and capable of being backdriven.  
An analytical formulation to study the dynamic coupling 
term (µ) in the apparent inertia matrix at the PFVA input was 
studied. This was based on an equivalent single-link model 
for a 1-DOF nonlinear mechanism. Specifically, the variation 
of µ w.r.t the relative scale factor or ρ (ratio of gear ratios of 
the force and velocity inputs) was studied. A limit analysis 
(ρ→∞) was carried out on the apparent inertia matrix to 
understand the limiting dynamics. It was shown that in the 
limit (ρ→∞) the two inputs to the PFVA were decoupled 
w.r.t. inertial torques. In other words: 
• The velocity input does not see a significant apparent 
inertia. 
• The force input manages almost all of the inertia of the 
output.  
The analytical formulation was illustrated by means of a 
numerical simulation with a crank-slider mechanism 
incorporating a PFVA input. Results from this simulation 
corroborated the analytical formulation. It was observed that 
as the relative scale factor (represented by ρ) was decreased 
(i.e. the sub-systems tend towards behaving as “equal” 
systems) the dynamic coupling between the systems 
increased. Physically, this means that a PFVA design 
configuration where the two sub-systems have comparable 
gear ratios has almost no utility since the inertia torque of 
one of the inputs is predominantly consumed to accelerate 
the other, thus reducing the actuator’s overall efficiency.  
 
6 
VII. FUTURE WORK 
In this section we will present two limitations that are not 
considered in this paper which are suggested for future work, 
(1) the physical limitation on the choice of a high value for ρ, 
and (2) a caveat on the disturbance of the force sub-system 
(FSS) due to the operation of the velocity sub-system (VSS).   
A. Physical Limitations on the Choice of ρ 
The physical limitations on the choice of a high value for 
the Relative Scale Factor (ρ) arise from the geometry of the 
planetary gear train. It is necessary to study this issue in 
greater detail.  
B. Disturbance Analysis of FSS Due to VSS 
In our discussion of the reflected inertia issue (Section. 
IV), we do not consider the disturbance imposed on the force 
sub-system due to the operation of the velocity sub-system. 
To address this issue, we suggest that a spring-mass-damper 
model of the FSS and VSS be considered such that the 
damping and spring-rate (respectively representing viscous 
friction and stiffness) are formulated in terms of their (FSS 
and VSS) gear ratios.  
VIII. ACKNOWLEDGEMENTS 
This research was partially funded by the Department of 
Energy (DOE) grant no. DE-FG52-2004NA25591, under the 
University Research Program in Robotics (URPR).  
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