Design of a Portable Low-Cost Impedance Analyzer

Abdulwadood Al-Ali

, Ahmad Elwakil

, Abdelaziz Ahmad

and Brent Maundy

Dept. Elect. Computer Eng., University of Calgary, Calgary, Canada

Dept. Elect. Computer Eng., University of Sharjah, Sharjah, U.A.E.

Keywords:

Bio-Impedance, Impedance Spectroscopy, Impedance Analyzer.

Abstract:

Impedance analyzers available in the market are mostly bulky and often very expensive. In this paper, a

low-cost, portable impedance analyzer is designed and implemented. The design utilizes the well-known,

impedance network analyzer chip AD5933 and is capable of measuring a spectrum of impedances in the range

5 Hz to 100 kHz from 10 Ω to 100 kΩ. Its speciﬁcations allow it to be used in agriculture for monitoring the

bio-impedance of fruits in different stages of their lives, especially during the growth period while maintaining

low-cost.

1 INTRODUCTION

Impedance spectroscopy is the study of the small-

signal electrical response of an object to yield useful

information about its structure “from mass transport,

rates of chemical reactions, corrosion, and dielec-

tric properties, to defects, microstructure, and com-

positional inﬂuences on the conductance of solids”

(Barsoukov and Macdonald, 2005). Any property

that affects the ﬂow of current in a certain material

can be investigated and studied through impedance

spectroscopy (Barsoukov and Macdonald, 2005).

Impedance spectroscopy has also been used exten-

sively to investigate the behavior of biological tis-

sues. Particularly monitoring the vitality of a fruit

through different stages of its life (Rose et al., 2013)

(Jamaludin et al., 2015). By measuring the impedance

spectrum of a fruit, important properties can be cor-

related to this impedance such as the acidity and

sugar content (Borges et al., 2012; V

ain

a and Repo,

2000). The frequency range 10 Hz to 100 kHz, is

satisfactory for most fruits. In that range, most fruits

have an impedance magnitude between 10 Ω to 100

kΩ.

Few methods were previously discussed to ex-

tract the Cole-Cole impedance module (Cole and

Cole, 1941), such as those in (Freeborn et al., 2013),

(Maundy et al., 2015) and (Valente and Demos-

thenous, 2016). Meanwhile, there are hardly any

portable low-cost impedance analyzers in the mar-

ket that can be employed on a wide scale. Recall

that agricultural applications cover large areas of land

hence the need for a battery operated low-cost wire-

less device.

In this work, we use the commercial AD5933

impedance analyzer chip along with an Atmel AT-

mega328P micro-controller unit (MCU) to achieve

this task. The MCU sets the sweeping parameters in

the AD5933 registers (the excitation voltage, the start

frequency, the frequency increment and the number

of steps) while managing the measured impedance

data to be stored on a MicroSD card before being

sent through Bluetooth to a PC for further processing.

Many recently proposed impedance analyzer designs

(Hoja and Lentka, 2013; Breniuc et al., 2014; Simic,

2013; Chabowski et al., 2015) have also employed the

AD5933 since it is the only single chip impedance an-

alyzer available in the market. However, overcoming

its internal design limitations is not straight forward,

as shall be explained below.

2 SYSTEM DESIGN

The proposed system, whose complete picture is

shown in Fig. 1 uses an ATmega328P to control the

AD5933 through its I

C interface. To achieve, porta-

bility the measured impedance data is saved into an

SD card and sent afterwards through Bluetooth to a

PC using an HC-05 Bluetooth module. This module

was chosen since it is widely used and well known for

it is ﬂexibility in choosing the baud rate, compatibil-

ity, low cost and low power consumption. The system

is also provided with two 3.7V batteries of 4400mAh

104

Al-Ali A., Elwakil A., Ahmad A. and Maundy B.

Design of a Portable Low-Cost Impedance Analyzer.

DOI: 10.5220/0006121901040109

In Proceedings of the 10th International Joint Conference on Biomedical Engineering Systems and Technologies (BIOSTEC 2017), pages 104-109

ISBN: 978-989-758-216-5

to achieve full portability.

2.1 AD5933 and Analog Front-End

The AD5933 chip uses a voltage-controlled oscillator

as an excitation signal. It has a precise direct dig-

ital synthesizer (DDS) and impedance measurement

is done by sensing the current going through the un-

known impedance under test, converting it to a volt-

age and then using an internal 12-bit analog to digital

converter (ADC) along with a Discrete Fourier Trans-

form (DFT) engine to extract the real (R) and imagi-

nary (I) parts of the impedance. The extracted R and

I values are saved in the chip’s registers which can

be accessed through an I

C interface. However, the

AD5933 has the following limitations:

2.1.1 Frequency Range

The AD5933 has the ability to do measurements

within the frequency range 1 kHz to 100 kHz with-

out any external components. The lower limit of this

frequency range is affected by the ADC sampling rate

which in turn deﬁnes the resolution of the DFT as

shown by equations (1) and (2) (Devices, 2012)

ADC Sampling rate =

MCLK

(1)

DFT Resolution =

ADC Sampling rate

1024

(2)

Using the internal on chip oscillator, the excitation

frequency can’t go below 1 kHz since it is provided

with a 16.778 MHz clock that will therefore result in a

1.04 MHz sampling rate which will limit the DFT res-

olution to 1 kHz. For the excitation signal frequency

to go below 1 kHz, the clock that drives the AD5933

has to be changed for each range of frequencies. The

authors of (Chabowski et al., 2015) showed that the

excitation signal frequency ( f

) can be chosen pre-

cisely and that the spectral leakage and the spikes in

the current to voltage converter can be avoided by us-

ing equation (3) with integer values of k between 16

and 32 (Devices, 2012).

= k ·

MCLK

1024 ×16

(3)

Using this equation, we control the master clock

(MCLK) using an external programmable oscilla-

tor which lowered the limit of the frequency to 5

Hz. However, the upper frequency limit cannot be

changed since it was limited to 100 kHz by the anti-

aliasing ﬁlter located before the ADC internal to the

chip.

2.1.2 DC Cancellation

Although the AD5933 has a perfect DDS core that can

provide very precise excitation signals at different fre-

quencies, this excitation signal has a DC-bias which

is different for each excitation amplitude. A DC volt-

age difference across biological cells under test might

cause polarization (Chabowski et al., 2015). There-

fore, a high pass ﬁlter is necessary to cancel the DC

component of the excitation before reaching the un-

known impedance. We employed a passive RC ﬁlter

with a cutoff frequency of 135 mHz in our design,

which was a sufﬁcient solution for DC cancellation

and it did not add any complexity to the design.

2.1.3 Output Impedance

The AD5933 has an output impedance that depends

on the excitation amplitude and that can be relatively

high in some cases (Devices, 2012; Devices, 2013a).

To solve this problem, a buffer with a very low out-

put impedance was added to isolate the unknown

impedance from the chip (Devices, 2013c).

2.1.4 Impedance Range

The measurable impedance range is affected by the

linearity and the calibration process inside the chip.

The manufacturer circuit note recommends using a

simple inverting ampliﬁer with gain −R

f b

unknown

order to sense the current in the unknown impedance

and convert it to voltage (Devices, 2013b). The ADC

inside the chip is limited in terms of its input voltage

tothe range 15mV-5V (Chabowski et al., 2015). Since

the input of the ADC (V

ADC

) is given by

ADC

×−(R

f b

unknown

)×PGA

gain

×FilterGain

(4)

and since the on-chip PGA and ﬁlter both have unity

gain, the linearity of the ADC depends only on the

ratio R

f b

unknown

. Our extensive experiments have

shown that the linearity of the gain factor (used in the

calibration process) can only be preserved by keeping

the ratio R

f b

unknown

between

3.5

and 3.5. There-

fore, to expand the measurable magnitude of Z

unknown

a multiple R

f b

solution was adopted where four dif-

ferent values of R

f b

(33 Ω, 330 Ω, 3.3 kΩ and 33

kΩ) were switched into the circuit through two (single

pole, double throw) switches switch as needed (De-

vices, 2004).

2.2 Data Processing

The AD5933 needs to be calibrated with a known

impedance by calculating the gain factor which repre-

Design of a Portable Low-Cost Impedance Analyzer

105

(a)

(b)

Figure 1: The designed portable impedance analyzer. (a) PCB implementation (b) System Design.

sents the gain of the system calculated using equation

(5)

GainFactor =





√

+ I

(5)

where R

is the calibration resistor value while R and

I are the values in the real and imaginary registers re-

spectively. The calibration methods mentioned in the

AD5933 datasheet are typically for small frequency

ranges. In the proposed design calibration is being

done using a lookup table to provide a gain factor

value for each point in the sweep which reduces the

BIODEVICES 2017 - 10th International Conference on Biomedical Electronics and Devices

106

error in the measurements signiﬁcantly. After calcu-

lating the impedance magnitude, the phase should be

also calibrated by using a resistor to get the system

phase that should be subtracted from the calculated

phase as

Unknown Phase = (Φ

measured

−Φ

System

) (6)

where Φ

System

is the phase of the system calcu-

lated using a known calibration resistor (where Φ =

tan

−1





3 EXPERIMENTAL RESULTS

The device was ﬁrst tested using off shelf resistive and

capacitive components with standard tolerances. The

measured magnitude and phase are shown respec-

tively in Figs. 2(a) and (b) for the following cases:

A 22 kΩ Resistor, 10 nF Capacitor and an RC com-

bination of 330 Ω series with 10 nF. The theoretical

values are also plotted in the same ﬁgure.

The impedance of two different apples was then

measured using both our device and the industry

standard PSM3750 impedance analyzer (Newton 4th

LTD, UK) ﬁtted with an IAI ﬁxture (Impedance Anal-

ysis Interface) (4th LTD, 2005). The measurements

were done using gold plated electrodes and using the

same placing for both measurements to minimize the

error caused by electrodes place and type (Freeborn

et al., 2016). The bode plot for both the magnitude

and the phase is shown in Fig. 3 while the Nyqust

plot is shown in Fig. 4. It is clear that the device pro-

vides acceptable results in comparison with one of the

best devices in the market albeit with portability and

very low cost of around $150. Using an optimization

and curve ﬁtting algorithm to the measured data us-

ing our device, a double dispersion Cole-Cole model

was constructed as shown in Fig. 5 (where s = jω)

with the values in Table 1, and the Nyquist plot from

the model is shown also in Fig. 4. The device test-

ing showed that it draws around 170 mA in the worst

case and is able to work for around 24 hours with the

provided 4400 mAh batteries.

Table 1: Fitting model values.

Component Apple #1 Apple #2

∞

(Ω) 2.1947 k 1.4432 k

(Ω) 90.992 k 24.229 k

(Ω) 25.2579 k 45.323 k

(F) 9.7962E-07 2.3946E-08

0.8078 0.7383

(F) 3.2705E-08 6.9596E-07

0.7138 0.96447

22 kΩ Measured

10 nF & 330 kΩ Measured

10 nF Measured

22 kΩ Calculated

10 nF & 330 kΩ Calculated

10 nF Calculated

Impedance (Ω)

100

10k

10M

Frequency (Hz)

(a)

22 kΩ Measured

10 nF & 330 kΩ Measured

10 nF Measured

22 kΩ Calculated

10 nF & 330 kΩ Calculated

10 nF Calculated

Phase (Degree)

−150

−125

−100

−75

−50

−25

Frequency (Hz)

(b)

Figure 2: Impedance (a) magnitude and (b) phase measure-

ments from off shelf discrete components compared to ac-

tual values.

4 CONCLUSION

A portable low cost impedance analyzer was designed

and implemented. The device can be left in the ﬁeld

to do continuous measurements for around 24 hours

and the data can be obtained wirelessly afterwards for

a low cost of around 150$. It can measure impedance

between 10 Ω and 100 kΩ, in a frequency range from

Design of a Portable Low-Cost Impedance Analyzer

107

Impedance Apple #1

Phase Apple #1

Impedance Apple #2

Phase Apple #2

|A| Impedance Apple #1

|A| Phase Apple #1

|A| Impedance Apple #2

|A| Phase Apple #2

Impedance (Ohm)

4×10

5×10

Phase (Degree)

−90

−80

−70

−60

−50

−40

Frequency (Hz)

10 100 1000 10

Figure 3: Comparison of measured phase and magnitude

using the proposed device and the PSM3750-IAI results.

|A| measurements Apple #1

Proposed system Meas. Apple #1

Fitted data Apple #1

Fitted data Apple #2

Proposed system Meas. Apple #2

|A| measurements Apple #2

-ImZ

2.5k

7.5k

10k

12.5k

15k

17.5k

ReZ

0 10k 20k 30k 40k

Figure 4: Impedance Nyquist plot measured using the pro-

posed device compared to PSM3750-IAI measurements.

1 2

∞

Figure 5: Double dispersion Cole-Cole ﬁtting Model.

5 Hz to 100 kHz with a simple low-cost design. Such

a device is very useful for studying a living object

through different stages of its life without interrupt-

ing its natural behaviour. In agriculture the availabil-

ity of such an impedance analyzer makes it possible

to determine a lot of information about the crops even

before harvest, such as what practices contribute to

the quality of the crops, the perfect time for harvest,

determining the level of certain chemicals in the crops

and many other factors.

REFERENCES

4th LTD, N. (2005). IAI Impedance Analysis Interface user

manual.

Barsoukov, E. and Macdonald, J. (2005). Impedance Spec-

troscopy: Theory, Experiment, and Applications. John

Wiley & Sons, 2 edition.

Borges, E., Matos, A., Cardoso, J., Correia, C., Vasconce-

los, T., and Gomes, N. (2012). Early detection and

monitoring of plant diseases by bioelectric impedance

spectroscopy. In Bioengineering (ENBENG), 2012

IEEE 2nd Portuguese Meeting in, pages 1–4. IEEE.

Breniuc, L., David, V., and Haba, C.-G. (2014). Wearable

impedance analyzer based on AD5933. In Electri-

cal and Power Engineering (EPE), 2014 International

Conference and Exposition on, pages 585–590.

Chabowski, K., Piasecki, T., Dzierka, A., and Nitsch, K.

(2015). Simple wide frequency range impedance me-

ter based on ad5933 integrated circuit. Metrology and

Measurement Systems, 22(1):13–24.

Cole, K. S. and Cole, R. H. (1941). Dispersion and absorp-

tion in dielectrics i. alternating current characteristics.

The Journal of Chemical Physics, 9(4):341–351.

Devices, A. (2004). ADG849 3 V/5 V CMOS 0.5 SPDT/2:1

Mux in SC70 Data Sheet.

Devices, A. (2012). Evaluation Board User Guide UG-364.

Devices, A. (2013a). 1 MSPS, 12-Bit Impedance Converter,

Network Analyzer AD5933 Datasheet. Rev. E.

Devices, A. (2013b). AD5933 Circuit Note. Rev. A.

Devices, A. (2013c). AD8605/AD8606/AD8608 Datasheet.

Rev. N.

Freeborn, T. J., Elwakil, A. S., and Maundy, B. J. (2016).

Electrode location impact on cole-impedance param-

eters using magnitude-only measurements. In IEEE

59th Int. Midwest Symposium on Circuits and Systems

(MWSCAS), volume 1, pages 21–24. IEEE.

Freeborn, T. J., Maundy, B., and Elwakil, A. S. (2013).

Cole impedance extractions from the step-response

of a current excited fruit sample. Comput. Electron.

Agric., 98:100–108.

Hoja, J. and Lentka, G. (2013). A family of new gener-

ation miniaturized impedance analyzers for technical

object diagnostics. Metrology and Measurement Sys-

tems, 20(1).

Jamaludin, D., Aziz, S. A., Ahmad, D., and Jaafar, H. Z.

(2015). Impedance analysis of labisia pumila plant

water status. Information Processing in Agriculture,

2(3):161–168.

Maundy, B., Elwakil, A., and Allagui, A. (2015). Ex-

tracting the parameters of the single-dispersion cole

BIODEVICES 2017 - 10th International Conference on Biomedical Electronics and Devices

108

bioimpedance model using a magnitude-only method.

Comput. Electron. Agric., 119(C):153–157.

Rose, E. J., Pamela, D., and Rajasekaran, K. (2013). Apple

vitality detection by impedance measurement. Inter-

national Journal of Advanced Research in Computer

Science and Software Engineering, 9:144–148.

Simic, M. (2013). Realization of complex impedance

measurement system based on the integrated circuit

ad5933. In Telecommunications Forum (TELFOR),

2013 21st, pages 573–576.

ain

a, A. and Repo, T. (2000). Impedance spectroscopy

in frost hardiness evaluation of rhododendron leaves.

Annals of Botany, 86(4):799–805.

Valente, V. and Demosthenous, A. (2016). Wideband fully-

programmable dual-mode CMOS analogue front-end

for electrical impedance spectroscopy. Sensors,

16(8):1159.

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