A NEW ALGORITHM FOR DATA HIDING USING OPAP AND MULTIPLE KEYS

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International Journal of Modern Trends in Engineering
and Research
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e-ISSN: 2349-9745
p-ISSN: 2393-8161
A NEW ALGORITHM FOR DATA HIDING USING OPAP
AND MULTIPLE KEYS
V.Eswari1
, G.Arumugam2
1
P.G. Student Dept. of ECE, Seshachala Institute of Technology
2
Assistant Professor, Dept. of ECE, Seshachala Institute of Technology
Abstract—Steganography gained significance in the past few years due to the increasing need
for providing secrecy in an open environment like the internet. With almost anyone can
observe the communicated data all around, steganography attempts to hide the very existence
of the message and make communication undetectable. In this paper we propose a modern
technique with Integer Wavelet transform (IWT) and double key to accomplish high hiding
capability, high security and good visual quality. Here cover image is transformed in to
wavelet transform co-efficients and the coefficients are selected randomly by using Key-2 for
embedding the data. Key-1 is used to calculate the number of bits to be embedded in the
randomly selected coefficients. Finally the Optimum Pixel Adjustment Process(OPAP) is
applied to the stego image to reduce the data embedding error.
Keywords- Steganography, Integer wavelet transform (IWT), Optimum Pixel Adjustment
Process(OPAP).
I. INTRODUCTION
Steganography is the art and science of hiding secret data in plain sight without being noticed
within an innocent cover data so that it can be securely transmitted over a network. The word
steganography is originally composed of two Greek words steganos and graphia, which
means "covered writing". Modern steganography is generally understood to deal with
electronic media rather than physical objects. Image steganography, of all has gained much
impetus and reputation in the recent past [1-18]. It comes under the general assumption that if
the feature is visible, the point of attack is evident. Thus the goal here is to always conceal the
coherence of the embedded data. The basic model of secret key steganography consists of
cover, secret data, stego image and key. Any digital file such as image , video, audio, etc can
be used as cover. Cover is also known as cover-object or cover image, is the plain digital
image with no secret data deposited in it. After the embedment it is called the stego image or
stego object [1, 2, 3, 10]. In image steganography [1] the critical data is camouflaged in a
cover image with immense dexterity.
The most popular hiding techniques are spatial domain based steganographic techniques and
transform domain based steganographic techniques. A useful, practical steganographic
method should be robust and should retain the hidden data even after many pixel values have
been modified. The other type of hiding method is the transform domain techniques which
appeared to overcome the robustness andimperceptibility problems found in the LSB
substitution techniques. There are many transforms that can be used in data hiding, the most
widely used transforms are; the discrete cosine transform (DCT) which is used in the
common image compression format JPEG and MPEG, the discrete wavelet transform (DWT)
and the discrete Fourier transform (DFT).One approach to this problem is to transform the

International Journal of Modern Trends in Engineering and Research (IJMTER)
Volume 01, Issue 05, [November - 2014] e-ISSN: 2349-9745, p-ISSN: 2393-8161
image and embed the data in the transformed pixels[4-6,8,9]. We say that the original image
exists in the spatial domain and the transformed image in the transformed domain. The data
is then embedded in the transformed pixels and the image is transformed back to the spatial
domain. The idea is that the image may now be exposed to various operations that will
change the pixels, but when this modified image is transformed again, the hidden data will
still be embedded in the transformed pixels. The disadvantage of the DCT based
steganographic technique [9, 13], is the hiding capacity. Wavelet transform based stego
technique provides high capacity as much as possible. In [4] the secret message is embedded
into the high frequency and low frequency coefficients of the wavelet transform to high
hiding capacity, but it provides less PSNR at high hiding rate. In this paper we propose a new
modified version of the methodology in [4], which can embed a larger amount of data in
integer wavelet transform (IWT) domain with high PSNR.
II. RELATED WORKS
A. Integer Wavelet Transforms
Generally wavelet domain allows us to hide data in regions that the human visual system
(HVS) is less sensitive to, such as the high resolution detail bands (HL, LH and HH), Hiding
data in these regions allow us to increase the robustness while maintaining good visual
quality. Integer wavelet transform maps an integer data set into another integer data set. In
discrete wavelet transform, the used wavelet filters have floating point coefficients so that
when we hide data in their coefficients any truncations of the floating point values of the
pixels that should be integers may cause the loss of the hidden information which may lead to
the failure of the data hiding system.
To avoid problems of floating point precision of the wavelet filters when the input data is
integer as in digital images, the output data will no longer be integer which doesn't allow
perfect reconstruction of the input image [12] and in this case there will be no loss of
information through forward and inverse transform [11].
The Haar Wavelet Transform is the simplest of all wavelet transform. The four bands
obtained are LL, LH, HL, and HH which is shown in Fig 1. The LL band is called as
approximation band, which consists of low frequency wavelet coefficients, and contains
significant part of the spatial domain image. The other bands are called as detail bands which
consist of high frequency coefficients and contain the edge details of the spatial domain
image. Integer wavelet transform can be obtained through lifting scheme. Lifting scheme is a
technique to convert DWT coefficients to Integer coefficients without losing information. [5,
8].
Figure 1 Image and its transform domain bands
B. Forward Lifting scheme in IWT.
Step1: Column wise processing to get H and L
H = (Co-Ce) (1)

L = (Ce- │H/2│) (2)
Where Co and Ce is the odd column and even column wise pixel values.
Step 2: Row wise processing to get LL,LH,HL and HH,
Separate odd and even rows of H and L,
Namely, Hodd – odd row of H
Lodd- odd row of L
Heven- even row of H
Leven- even row of L
LH = Lodd - Leven (3)
LL = Leven - │LH / 2 │ (4)
HL = Hodd – Heven (5)
HH = Heven - │HL / 2 │ (6)
C. Reverse Lifting scheme in IWT
Inverse Integer wavelet transform is formed by Reverse lifting scheme. Procedure is similar
to the forward lifting scheme.
D. LSB Embedding
Simple LSB embedding [2]is detailed in this section. Consider a 8-bit gray scale image
matrix consisting m × n pixels and a secret message consisting of k bits. The first bit of
message is embedded into the LSB of the first pixel and the second bit of message is
embedded into the second pixel and so on. The resultant stego-image which holds the secret
message is also a 8-bit gray scale image and difference between the cover image and the
stego-image is not visually perceptible.
This can be further extended, and any number of LSB’s can be modified in a pixel.
The quality of the image, however degrades with the increase in number of LSB’s. Usually
up to 4 LSB’s can be modified without significant degradation in the message.
Mathematically, the pixel value ‘P’ of the chosen pixel for storing the k-bit message Mk is
modified to form the stego-pixel ‘Ps’ as follows:
Ps=P-mod(P,2k)+Mk (7)
The embedded message bits can be recovered by
Mk=mod(Ps,2k) (8)
One method to recover the quality of the LSB substitution is Optimal Pixel adjustment
Process (OPAP)[2].
E. Optimal Pixel adjustment Process
The projected Optimal Pixel adjustment Procedure (OPAP) reduce the error caused by the
LSB substitution method. In OPAP method the pixel value is adjusted after the secret data is
concealed. It is done to improve the quality of the stego image without disturbing the data
hidden.
F. Adjustment Process
Let ‘n’ LSBs be substitute in each pixel.
Let d= decimal value of the pixel after the substitution.

d1 = decimal value of last n bits of the pixel.
d2 = decimal value of n bits concealed in that pixel.
If(d1~d2)<=(2^n)/2
then no adjustment is made in that pixel.
Else
If(d1<d2)
d = d – 2^n .
If(d1>d2)
d = d + 2^n .
This d is converted to binary and written back to pixel.
III. PROPOSED METHODOLOGY
Fig. 2 shows the proposed system is a high capacity steganography system. Preprocessing
includes R, G and B plane separation and Histogram modification. Then Integer wavelet
transform is applied to the cover image to get wavelet coefficients. Wavelet coefficients are
randomly selected by using key-2 for embedding the secret data. Key -2 is 8x8 binary matrix
in which ‘1’ represents data embedded in the corresponding wavelet coefficients and ‘0’
represents no data present in the wavelet coefficients.
Key-1(K1) is a decimal number varying from 1 to 4 and it will decide the number of bits to
be embedded in the cover object.
Figure 2 The Block Diagram of the Proposed Methodology
A. Algorithm (For Embedding of Data):
Step 1: Read the cover image as a 2D file with size of 256×256 pixels.
Step 2: R, G and B planes are separated.
Step 3: Consider a secret data as text file. Here each character will take 8 bits.

Step 4: Histogram adjustment[16] is done in all planes, Because, the secret data is to be
embedded in all the planes, while embedding integer wavelet coefficients produce stego-
image pixel values greater than 255 or lesser than 0. So all the pixel values will be ranged
from 15 to 240.
Step 5: Each plane is divided into 8×8 blocks.
Step 6: Apply Haar Integer wavelet transform to 8 × 8 blocks of all the planes, This process
results in LL1, LH1, HL1 and HH1 sub bands.
Step 7: Using Key-1(K1) calculate the Bit length(BL) for corresponding wavelet co-
efficients (WC), Here we used modified version of Bit length calculation used in [4]. Using
the following equation, we get the high capacity steganography.
Step 8: Using key-2 select the position and coefficients for embedding the ‘BL’ length data
using LSB substitution[2]. Here data is embedded only in LH1,HL1and HH1 subbands. Data
is not embedded in LL1 because they are highly sensitive and also to maintain good visual
quality after embedding data. An example of key-2 is shown below.
0 0 0 0 1 0 1 0
0 0 0 0 0 1 0 1
0 0 0 0 1 0 1 0
Key – 2 =
0 0 0 0 0 1 0 1 (10)
1 1 1 1 0 1 0 1
1 1 1 1 1 0 1 0
1 1 1 1 0 1 0 1
1 1 1 1 1 0 1 0
Step 9: Applying Optimal Pixel adjustment Procedure (OPAP) reduces the error caused by
the LSB substitution method.
Step 10: Take inverse wavelet transform to each 8×8 block and combine R,G&B plane to
produce stego image.
B. Algorithm (For Extracting of Data):
Step 1: Read the Stego image as a 2D file with size of 256 × 256 pixels.
Step 2: R, G and B planes are separated.
Step 3: Each plane is divided into 8×8 blocks.

Step 4: Apply Haar Integer wavelet transform to 8×8 blocks of all the planes, This process
results LL1,LH1,HL1 and HH1 subbands.
Step 5: Using Key-1 calculate the Bit length(BL) for corresponding wavelet co-
efficients(WC), using the ‘BL’ equation used in Embedding procedure.
Step 6: Using key-2 select the position and coefficients for extracting the ‘BL’ length data.
Step 7: Combine all the bits and divide it in to 8 bits to get the text message.
IV. ERROR METRICS
A performance estimate in the stego image is calculated by means of two parameters
namely, Mean Square Error (MSE) and Peak Signal to Noise Ratio (PSNR). The MSE is
calculated by using the equation,
(11)
where M and N denote the total number of pixels in the horizontal and the vertical
dimensions of the image Xi, j represents the pixels in the original image and Yi,j represents
the pixels of the stego-image.
The Peak Signal to Noise Ratio (PSNR) is expressed as
V. RESULT AND DISCUSSION
In this present implementation, Flower and Elephant 256 × 256 × 3 color digital images
have been taken as cover images, as shown in Figure 3&4- a,b, c & d, tested with key-2(key-
key - 1(K1) = 1
Various
key -2
Cover Image
Total No.
of bits
embedded
Channel - I Red Channel - II Green Channel - III Blue
MSE PSNR(dB) MSE PSNR(dB) MSE PSNR(dB)
Key - A
Flower 59168 1.31219 53.9016 1.86553 50.8456 1.05667 55.7828
Elephant 80512 3.34099 45.7841 3.10357 46.4244 2.80991 47.2878
Key - B
Flower 78696 1.32099 53.8436 1.86851 50.8317 1.06836 55.6872
Elephant 92968 3.31004 45.8649 3.10463 46.4214 2.79836 47.3235
Key - C
Flower 104944 1.32786 53.7986 1.86316 50.8566 1.07731 55.6148
Elephant 196480 3.37844 45.6873 3.14449 46.3106 2.82475 2.82475
Key - D
Flower 110320 1.29164 54.0388 1.84346 50.949 1.04401 55.8875
Elephant 252784 3.36729 45.716 3.14812 46.3006 2.81612 47.2686
Key - E
Flower 240840 1.33505 53.7517 1.88163 50.7709 1.0914 55.5019
Elephant 335560 3.40763 45.6126 3.18555 46.1979 2.8945 47.0301

E) and various key-1s. The effectiveness of the stego process proposed has been studied by
calculating MSE and PSNR for the two digital images in RGB planes and tabulated.
First analysis is used to select the Key-2 for random selection of coefficients for
embedding data (in this analysis Key-1 has been set as K1=1) and the results are tabulated in
Table-I for various Key-2 using the proposed method. From table –I we will understand that
Key-E provides high capacity and Key – A provides low capacity.
In the second analysis, Key-E will be taken with various ‘K1’ values and the results are
tabulated in Table-II. Combining Key-E with K1=4 will yield high hiding capacity with high
PSNR.
Table – II MSE, PSNR for fixed Key-2(Key-E) with varying Key-1 in all the three planes
Figure 3. K1=1,2,3 & 4 respecively
Key-1
Cover
Image
Total No. of
bits
embedded
Channel - I Red Channel - II Green Channel - III Blue
MSE PSNR(d
B)
MSE PSNR(
dB)
MSE PSNR(d
B)
K1=1 Flower 240840 1.33505 53.7517 1.88163 50.7709 1.0914 55.5019
K1=2 Flower 299256 1.35302 53.6355 1.88619 50.7499 1.0997 55.4357
K1=3 Flower 307280 1.34458 53.6899 1.87415 50.8055 1.0992 55.4397
K1=4 Flower 348192 1.35817 53.6025 1.87792 50.7881 1.0911 55.504
K1=1 Elephant 335560 3.40763 45.6126 3.18555 46.1979 2.8945 47.0301
K1=2 Elephant 348192 3.39305 45.6498 3.16413 46.2565 2.8627 47.126
K1=3 Elephant 370288 3.38845 45.6616 3.16842 46.2447 2.8782 47.0791
K1=4 Elephant 435304 3.38991 45.6578 3.18234 3.18234 2.8663 47.1151

Figure 4. K1=1,2,3 & 4 respecively
VI. CONCLUSION
Data hiding with steganography has two primary objectives firstly that steganography should
grant the maximum possible payload, and the second, embedded data must be undetectable to the
observer. It should be stressed on the fact that steganography is not meant to be robust. It was found
that the proposed method gives high payload (capacity) in the cover image with very little error.
This is of course on the expense of reducing PSNR and increasing the MSE. By modifying the
equation (9) to get high capacity for the various applications using wavelet transform, Key-1 and
Key-2 provides high protection. The drawback of the proposed method is the computational
overhead. This can be reduced by high speed computers.
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A NEW ALGORITHM FOR DATA HIDING USING OPAP AND MULTIPLE KEYS

A NEW ALGORITHM FOR DATA HIDING USING OPAP AND MULTIPLE KEYS

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