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Engineering, Technology & Applied Science Research Vol. 11, No. 1, 2021, 6687-6690 6687 
 

www.etasr.com Ali et al.: Analyzing the Impact of Loop Parameter Variations on the Transient Response of Second … 

 

Analyzing the Impact of Loop Parameter Variations 

on the Transient Response of Second Order Voltage-

Switched CP-PLL 
 

Darshna Narwani  

Department of Electronic Engineering 
Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
darshna.narwani@muetkhp.edu.pk 

Ehsan Ali 

Department of Electronic Engineering 
Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
ehsan.ali@quest.edu.pk 

Ahsan Murtaza Bughio 

Department of Electronic Engineering 
Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
ahsan.murtaza@quest.edu.pk 

Nasreen Nizamani 

Department of Electronic Engineering 
Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
nasreen_nizamani@quest.edu.pk 

Shahid Hussain Siyal 

Department of Energy and Environment Engineering 

Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
shahidsiyal@quest.edu.pk 

Abdul Rafay Khatri 

Department of Electronic Engineering 

Quaid-e-Awam University of Engineering, Science and 

Technology 

Nawabshah, Pakistan 
arkhatri@quest.edu.pk 

 

 

Abstract-The analysis of the behavior of Charge Pump Phase-

Locked Loop (CP-PLL) is a challenging task due to its mixed-

signal architecture. Out of its two types, i.e. Current Switched 

CP-PLL (CSCP-PLL) and Voltage Switched CP-PLL (VSCP-

PLL), the prior produces symmetrical pump currents, resulting 

in an appropriate transient performance to be analyzed. The loop 

parameters are important to set the gain, target frequency, and 

assure the stability of the system. The more important is the 

bandwidth of the loop, which is dependent on the loop filter 

parameters to perform stable operation and locking time. In this 
paper, the impact of loop parameter variations on the overall 

transient behavior of the system is investigated. It has been 

shown that loop parameters play an important role to ease the 
design of mixed-signal PLLs. 

Keywords-charge pump PLL; voltage switched charge pump; 

transient analysis; loop parameter variation; behavioral model 
simulations 

I. INTRODUCTION  

The CP-PLL is a mixed-signal architecture (i.e. a 
combination of digital and continuous time components) [1]. It 
is an essential building block in a variety of applications 
ranging from Radio Frequency (RF) communication like FM 

modulation and demodulation, frequency synthesis and 
multiplication, frequency discrimination, tone decoding, data 
synchronization and conditioning, voltage-to-frequency 
conversion and clock and data recovery, Doppler shift 
frequency, mobile and wireless communication, servo control 
systems, and smart system applications [2-6]. As detailed in 
[7], CP-PLL is a widely used subsystem due to its theoretical 
zero static phase shift, and is also one of the simplest and most 
effective PLL-design platforms. 

The basic components of a CP-PLL are described in [1]. 
The CP-PLL works as a negative feedback device, in which its 
servo mechanism synchronizes the phase and frequency of 
divided feedback signal υdiv(t) produced by an oscillator with 
the phase and frequency of the reference signal υref(t). The 
phase error between υref(t) and υdiv(t) signals is detected by the 
digital Phase-Frequency Detector (PFD) which then commands 
the Charge Pump (CP) circuit to compensate the error signal by 
producing correction signal (in the form of current or voltage 
signal during this interval) [6]. As a result, a subsequent pulse 
width modulated current signal is produced by the combined 
PFD-CP operation, which is the supplied to the Loop Filter 
(LF) circuit to establish a fine-tuned quasi-dc signal, driving 

Corresponding author: Ehsan Ali



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www.etasr.com Ali et al.: Analyzing the Impact of Loop Parameter Variations on the Transient Response of Second … 

 

the Voltage Controlled Oscillator (VCO) to produce the output 
frequency [9].  

A CP-PLL basically operates in nonlinear acquisition and 
tracking regions. It is unlocked in the acquisition region and 
works in a strongly nonlinear pull-in process, while in the 
tracking region, it is locked and follows the phase error 
variations within the [−2π, 2π] range [6, 10, 13]. There are two 
types of CP-PLL on the basis of its configuration, namely 
Voltage Switched Charge Pump (VSCP) and Current Switched 
Charge Pump (CSCP) [6, 8, 9, 12]. Most research attention has 
been given to the Current Switched Charge Pump (CSCP) PLL, 
as it ideally provides a symmetrical pump current, resulting in 
suitable transient response which is simpler and easier to be 
analyzed, as compared to that of Voltage Switched Charge 
Pump (VSCP) which delivers asymmetrical pump currents to 
the electrical load of the LF, resulting in varying gain of the 
control system and hence affecting its tracking ability. 
However, the cost-effective and simplified design of constant 
voltage source has made VSCP-PLL commercially popular 
among charge pump PLLs [9]. So far, various models and 
methods have been developed for the analysis of VSCP-PLL 
behavior but this field still requires qualitative research for 
more efficient modeling and result accuracy in order to 
facilitate modern communication and control systems with 
improved tracking performance and stability. 

In this paper, analysis has been conducted to determine the 
way the variation in loop parameters affects the transient 
response of the 2

nd
 order VSCP-PLL, using behavioral model 

simulations. The results are compared with those obtained from 
the linear transfer function model of VSCP-PLL in the locked 
state to further verify its validation for the analysis of VSCP 
behavior.  

II. THE PECULIAR EFFECT IN THE VSCP-PLL ARCHITECTURE 

The CP-PLL is one of the most utilized circuits in 
frequency synthesis function. Due to the design simplicity of 
charge-pump, VSCP-PLL architecture is preferred in most 
applications. The VSCP introduces a peculiar effect in the form 
of non-constant current ip(t):  

DN

NULL

UP

RR

tV

RR

tV

ti

→

→

→













+
−

+

−

=

10

c1SS

10

c1DD

p
)(
              0           

 
)(

)(
υ

υ

    (1) 

Since the gain of the phase detector is associated with the 
pump current, thus it affects the overall loop gain of the system 
[8]. Moreover, the engineers prefer the parameters of the linear 
model. The prediction of the system behavior of the CP-PLL is 
based on the following assumptions: 

First of the all, the CP-PLL is under locked condition, thus 
the phase error is between [0, 2π] and PFD is in the linear 
range. Second, the output transfer characteristics of the VCO 
are considered linear over the tuning range. Considering these 
conditions, the Linear Time Invariant (LTI) system is 
represented with the transfer function, which is enough to 
predict the average behavior of the system:  

������ = ɸ	
����ɸ
����� =
	����������� 	���������	��

��	�����
�������	������	����� 			    (2) 

Generally, two parameters (ζ, ωn) are important to predict 
the system behavior using the linear approach: 

vs v DD

n

0 1 1

1

2 ( R )

1
[ ]

2

2

vs
vs n

v DD

K V

N R C

K V

N

ω

ω
ζ τ

=
+

= +
    (3) 

The value of !"� is not the same as of ! for the current 
switched CP-PLL as given in [10]. The linear model 
represented by (2) is only valid in the locked state. If the output 
frequency deviates from the center frequency due to frequency 
excursions or non-linear function of the VCO characteristics, 
then the linear representation may not be efficient enough to 
predict non-linearities at even a small scale. Therefore, the 
impact of such peculiar effect complicates the analysis of 
VSCP-PLL systems. Thus, more rigorous approaches may be 
required for analyzing the weakness of such systems in 
following the ramping system behavior. One of the best 
approaches apart from the circuit level are the behavioral 
modeling of such system [10, 11], which can be sufficient to 
predict non-linear acquisition region of such complex system.  

III. TRANSIENT ANALYSIS OF 2ND ORDER VSCP-PLL 

The P-PLL has a non-linear switching behavior and is 
initial condition dependent. Generally, the CP-PLL operates in 
two regions, non-linear acquisition region (during unlocking) 
and tracking region (during locking). Stable PLL operation 
may be predicted by the transfer function model if the 
following condition is true: 

#
����#$�� ≥ 10    (3) 
The sampling ratio in the pulse width modulated behavior 

of VSCP-PLL is set by (3) [14]. Generally the information is 
hidden in two parameters: damping factor (ζ) and natural 
angular frequency (ωn) ,which can be sufficient and a starting 
point toward the stability condition [15]. A set of parameters 
was chosen to perform behavioral simulations in SIMULNIK. 
The transient behavior (in symmetrical condition during 
locking) of a second order VSCP-PLL is shown in Figure 1. 
The symmetrical condition is only obtained when υctr(t)=VDD/2. 

A. Loop Parameter Variations (Changing N) 

The VSCP-PLL loop is defined by parameters designed to 
achieve stability and suitable transient characteristics. A VSCP-
PLL can be used as a frequency synthesizer; the divider circuit 
is implemented to perform this function. It can be difficult to 
design multiband VCO, thus by changing the value of N, the 
output frequency response that targets voltage can be changed 
easily. It can be observed that the slope of the rising voltage 
over the input of the VCO is not constant as a consequence of 
the weak dynamics of VSCP-PLL due to the non-constant 
pump current.  



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www.etasr.com Ali et al.: Analyzing the Impact of Loop Parameter Variations on the Transient Response of Second … 

 

 
Fig. 1.  Symmetrical transient behavior of the VSCP-PLL. 

 
Fig. 2.  The transient simulations by changing N. 

B. Loop Parameter Variations (Changing Kv) 

As discussed in the above subsection, it can be difficult to 
change the gain of the VCO (Kv), or implement multiband 
VCOs. The occurrence of non-linearities may impact the 
transient or steady state of the VSCP-PLL and may cause the 
system to unlock at any stage. Thus, in behavioral simulations 
it may be easy to change the Kv, however this is quite 
challenging during the design process. By changing the gain, 
the target voltage is changed in a similar way as changing the N 
under the locked condition: 

v

ref
target )(

K

Nf
t

×
=υ     (4) 

From (4), it is easy to predict that the transient behavior can 
be changed by changing the linear gain (Kv) of the VCO or N. 
Similarly, it can be observed that the VSCP-PLL exposes its 
asymmetrical behavior during non-linear pull in process during 
locking, as it is evident from the voltage steps during the UP 
and DN cycles (Figure 3). The target frequency can be changed 
either by changing N or Kv. Since the divider can be 
programmable, therefore it is more easier to modulate N. 
Obviously, when the CSPL-PLL system is locked at different 
target frequencies, the transient parameters like rise time (tr), 
peak time (tp), percent overshoot and settling time (tr) vary. The 
two dynamic time parameters given in Table I show how the 
response is changing when the system is locked in symmetrical 
or asymmetrical condition. Moreover, the linear and behavioral 
model parameters are constant when the system is locked under 
symmetrical conditions, however these parameters divert when 
considering the symmetrical situation. It can be concluded that, 
the linear model is only valid in the symmetrical condition for a 
second order VSCP-PLL unlike CSCP-PLL. 

 
Fig. 3.  The transient simulations for different values of Kv. 

TABLE I.  TRANSIENT PARAMETER VARIATION AT DIFFERENT KV 
WITH SYMMETRICAL AND ASYMMETRICAL BEHAVIOR 

Transient parameter 
Linear model 

(theoretical) 

Behavioral model 

 

At Kv=48MHz/V (()*+ �,� = -��� ) 
ζ
vs

=0.3070, ./"�=4.3853x104 rad/s, �01234
��34 = 143.2787 

tp 75.2 us 74 us 

tr 45.1 us 45 us 

At Kv=96MHz/V (()*+ �,� 5 -��� ) 
ζ
vs

=0.4186, ./"�= 6.2017x104rad/s, �01234
��34 = 101.3133 

tp 55.7 us 47 us 

tr 35.5u s 32 us 

At Kv=31.68MHz/V (()*+�,� 6 -��� ) 
ζ
vs

= 0.2586, ./"�= 3.5626 x104 rad/s, �01234
��34 = 176.3639 

tp 91.286 us 126 us 

tr 53.24 us 52  us 

 

C. Loop Filter Parameter Variations  

The LF parameters are important in obtaining stable system 
operation, as the overall bandwidth and damping of the system 
is related to the LF parameters. Moreover, there is residual 
damping due to the inclusion of the VSCP architecture. 

1) Impact of Changing R1 on Transient Response  

The transient response of the 2
nd
 order VSCP-PLL for 

various values of R1 at symmetrical condition of the charge-
pump voltage, is shown in Figure 4. It can be observed that the 
speed of response is affected and the system behavior is more 
damped as the value of R1 is increasing (Figure 5). It is worth 
noting that when the R1 is set to zero the system expanses its 
weakly damped response. It is evident from (3) that the system 
has residual damping due to the VSCP structure. Changing R1 
has a slight impact on the natural frequency of the system.  

2) Impact of Changing C1 on Transient Response  

The LF parameters are very important in establishing the 
quasi-dc voltage at the input of the VCO in order to produce a 
signal proportional to the control voltage. The time constant of 
the LF cirucit sets the speed of the VSCP-PLL which highly 
impacts transient parameters like rise time and locking time. As 



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shown in Figures 5-6, the transient simulation varies due to the 
variation of C1. The time constant is increasing and the natural 
angular frequency of the system is decreasing. However, there 
is less impact on the damping of the system.  

 

 
Fig. 4.  Transient behavior of VSCP-PLL at different values of R1 

(VDD=4V, R0=2MΩ, fref=1MHz, N=96, Kv=48MHz/V, R1=10KΩ,  
R1=0, 5KΩ ,10KΩ and 15KΩ). 

 
Fig. 5.  Transient behavior of VSCP-PLL at different values of C1 

(VDD=4V, R0=2MΩ, fref=1MHz, N=96, Kv=48MHz/V, R1=10KΩ, 
C1=100pF, 130pF, and 160pF). 

 
Fig. 6.  Impact of varying capacitor C1 of the LF on the locking time of 

VSCP-PLL. 

IV. CONCLUSION 

In this paper, the impact of variations in loop parameters 
(Kv, N, and τ) on the VSCP-PLL’s transient behavior was 
investigated using behavioral simulations. The results revealed 
that the change in the divider ratio N and VCO gain Kv has 
direct impact on the overall transient characteristics as the loop 
gain is associated to charge pump current. By changing N and 
Kv, the locking time and the natural angular frequency ωn

vs 
of 

the system vary. Moreover, changing the values of C1 of the LF 
circuit under symmetrical pump current, also affects the ωn

vs
 

whereas varying the values of R1 of the LF circuit has little 
impact on the ωn

vs
 and the locking time of VSCP-PLL, 

however, it has significant influence on system’s damping 
response. These parameters highly affect the system’s transient 
characteristics such as rise time and peak. It was also shown 
that a VSC-based system exhibits weakly damped behavior 
even when the 71 is set to zero, unlike the CSCP based system 
[8], however, it leads to improved system stability [15].  

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