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Thursday, August 25, 2011

Bsnl 3G Data Plan

3G Prepaid Data Plans                                                                                                                                            ©Ravini .Inc
Data RCV in Rs.(Inclusive Service Tax)Day/Any time usage in GBNight * usage in GBTotal bundled free Usage in GBValidity (days)**Data Charges in Rs./10KB*** (except APN 'bsnlstream')Data Charges in Rs./MB***(For APN bsnlstream)
100
0.25
--
0.25
30
0.02
0.25
200
0.50
--
0.50
30
0.02
0.25
400
1
--
1
30
0.02
0.25
606
1
5
6
30
0.02
0.25
716
2
--
2
30
0.02
0.25
1102
10
--
10
30
0.02
0.25
1500
15
15
30
0.02
0.25
2000
22
22
30
0.02
0.25
2500
12
12
180
0.02
0.25
3000
35
35
30
0.02
0.25
5000
30
30
180
0.02
0.25
*11.00 PM to 07.00 AM
** This will increase the validity of main and dedicated accounts both.
*** Data charges beyond free usage shall be deducted from the available balance in his main account. Free data usage is available both from home LSA and while roaming.
Note : Price may vary from Circle to Circle by Rs.3(+/-) considering local market conditions etc.
3.2.2 Short term validity data recharge vouchers for 3G prepaid services
MRP of RCV in Rs. (Inclusive of Service Tax)
Service Tax in Rs.
Cost of RCV in Rs.
Free data usage in MB
Validity in days
10
0.93
9.07
20
1
25
2.33
22.67
50
3
50
4.67
45.33
100
7
Note: In case of STVs/Data RCVs, the circle can suitably adjust the MRP in the price band up to Rs.3 (+/-) of price mentioned in the website, considering the technical feasibility.
3.2.3 3G Data Top-up Voucher
Type of Voucher
MRP (Incl. of S. Tax)
Free Usage in MB
Validity
3G Data Top-up
Rs.197
500 MB
Nil

3.2.4 3G Combo Data Plan 

FMC/RCV for 3G Combo Data plan
Fixed Monthly Charges in Rs. (Postpaid)
RCV Amount in Rs. (Incl. of S. Tax) (Prepaid)
Free 3G Data Usage in MB
Total (Local+ National) Min
Total SMS
Local Video call in Min
300
331
300
300
300
30
500
551
500
1000
500
50
1000
1103
1024
2000
1000
100
2000
2206
3072
5000
2000
200

i) The MRP of Data RCV is inclusive of Service Tax @10.30%. Circles can suitably adjust the MRP in the price band upto Rs.3 (+/-) of above price considering the technical feasibility.
ii) The validity in case of 3G prepaid RCV is 30 days. The RCV will increase both main account and dedicated account validity.
iii) The free minutes voice/video calls, SMSs and data usage offered with plan are to be consumed within the validity period. No carry forward of unutilized freebies are allowed.
iv) Free data usage is available while national roaming also. However, free voice/video calls & SMSs are available from home LSA only.
v) Other charges and usage beyond free limits will be as per normal call charges i.e. base voice plan under 3G service.
vi) In case of data plan the customers not purchasing data card from BSNL has to activate through FRC 120.
vii) The tariff mentioned above is subject to technical feasibility of concerned IN.

3.3 Trial Pack :( Inclusive of Service Tax)
1
MRP of Trial pack in Rs. (Incl. of S. Tax)
Rs.121
2
Free usage in MB
300 MB
3
Validity in days*
15 days
Data charges for trial pack customers after use of 125MB / 300MB or 15 days expiry shall be as per his base plan.
*This will increase the validity of Main and dedicated accounts both.

Bsnl 2G Data Plan

 
                                  Prepaid 2G Data Card tariff plans:-                                                                              ©Ravini .Inc

MRP of RCV in Rs.^
Free data usage
Additional usage charge with pulse rate of 10KB
Validity in days
Day/Any time usage
Night Usage
Nil
Nil
Nil
Rs.0.02/10KB
NA
7
100 MB
Nil
Rs.0.02/10KB
1 day
13
200 MB
Nil
Rs.0.02/10KB
3 days
54
300 MB
3 GB
Rs.0.02/10KB
30 days
98
3 GB
Rs.0.02/10KB
30 days
219
4 GB
4 GB
Rs.0.02/10KB
30 days
270
10 GB
Rs.0.02/10KB
30 days
555
15 GB
Rs.0.02/10KB
180 days
a)^ MRP of RCV is inclusive of Service Tax @10.30%

b)The MRP in the price band upto Rs.3 (+/-) of above price considering the technical feasibility may be done at the circle level.

c)GPRS/Edge Services may be activated under prepaid mobile services without any minimum balance requirement.
d)The free data usage allowed is also applicable while in national roaming.
e) The usage charges beyond free usage will be same for Home LSA and roaming.
f) The base voice plan in case of postpaid 2G data plans will be Plan 99 and in case of prepaid data plans the tariff of Saral Anant plan. No Fixed Monthly Charges (FMC) will be recovered from the data plans for the base voice plan.

g)The RCVs mentioned above will increase both main and dedicated account validity.
2. The above, revised tariff will be allowed to all customers who want to take data plan from BSNL, irrespective of purchasing data card from BSNL or not.
Note:
In case of Assam, JK & NR LSAs instructions of DOT/TRAI regarding validity will be complied with.

Friday, August 19, 2011

How does the Internet work?


             How does the Internet work?

To help you understand how the Internet works, we'll look at the things that happen when you do a typical Internet operation


1.1. Names and locations

The first thing your browser has to do is to establish a network connection to the machine where the document lives. To do that, it first has to find the network location of the host ravivini.blogspot.com (‘host’ is short for ‘host machine’ or ‘network host';  is a typical hostname). The corresponding location is actually a number called an IP address (we'll explain the ‘IP’ part of this term later).
To do this, your browser queries a program called a name server. The name server may live on your machine, but it's more likely to run on a service machine that yours talks to. When you sign up with an ISP, part of your setup procedure will almost certainly involve telling your Internet software the IP address of a nameserver on the ISP's network.
The name servers on different machines talk to each other, exchanging and keeping up to date all the information needed to resolve hostnames (map them to IP addresses). Your nameserver may query three or four different sites across the network in the process of resolving ravivini.blogspot.com, but this usually happens very quickly (as in less than a second). We'll look at how nameservers detail in the next section.
The nameserver will tell your browser that ravivini.blogspot.com IP address is 152.19.254.81; knowing this, your machine will be able to exchange bits with ravivini.blogspot.com directly.

1.2. The Domain Name System

The whole network of programs and databases that cooperates to translate hostnames to IP addresses is called ‘DNS’ (Domain Name System). When you see references to a ‘DNS server’, that means what we just called a nameserver. Now I'll explain how the overall system works.
Internet hostnames are composed of parts separated by dots. Adomain is a collection of machines that share a common name suffix. Domains can live inside other domains. For example, the machine ravivini.blogspot.com lives in the .tldp.org subdomain of the .org domain.
Each domain is defined by an authoritative name server that knows the IP addresses of the other machines in the domain. The authoritative (or ‘primary') name server may have backups in case it goes down; if you see references to a secondary name server or (‘secondary DNS') it's talking about one of those. These secondaries typically refresh their information from their primaries every few hours, so a change made to the hostname-to-IP mapping on the primary will automatically be propagated.
Now here's the important part. The nameservers for a domain donot have to know the locations of all the machines in other domains (including their own subdomains); they only have to know the location of the nameservers. In our example, the authoritative name server for the .org domain knows the IP address of the nameserver for .tldp.org but not the address of all the other machines in .tldp.org.
The domains in the DNS system are arranged like a big inverted tree. At the top are the root servers. Everybody knows the IP addresses of the root servers; they're wired into your DNS software. The root servers know the IP addresses of the nameservers for the top-level domains like .com and .org, but not the addresses of machines inside those domains. Each top-level domain server knows where the nameservers for the domains directly beneath it are, and so forth.
DNS is carefully designed so that each machine can get away with the minimum amount of knowledge it needs to have about the shape of the tree, and local changes to subtrees can be made simply by changing one authoritative server's database of name-to-IP-address mappings.
When you query for the IP address of ravivini.blogspot.com, what actually happens is this: First, your nameserver asks a root server to tell it where it can find a nameserver for .org. Once it knows that, it then asks the .org server to tell it the IP address of a .tldp.org nameserver. Once it has that, it asks the .tldp.org nameserver to tell it the address of the host ravivini.blogspot.com.
Most of the time, your nameserver doesn't actually have to work that hard. Nameservers do a lot of cacheing; when yours resolves a hostname, it keeps the association with the resulting IP address around in memory for a while. This is why, when you surf to a new website, you'll usually only see a message from your browser about "Looking up" the host for the first page you fetch. Eventually the name-to-address mapping expires and your DNS has to re-query — this is important so you don't have invalid information hanging around forever when a hostname changes addresses. Your cached IP address for a site is also thrown out if the host is unreachable.

1.3. Packets and routers

What the browser wants to do is send a command to the Web server on ravivini.blogspot.com that looks like this:

GET /LDP/HOWTO/Fundamentals.html HTTP/1.0
Here's how that happens. The command is made into a packet, a block of bits like a telegram that is wrapped with three important things; the source address (the IP address of your machine), thedestination address (152.19.254.81), and a service number orport number (80, in this case) that indicates that it's a World Wide Web request.
Your machine then ships the packet down the wire (your connection to your ISP, or local network) until it gets to a specialized machine called a router. The router has a map of the Internet in its memory — not always a complete one, but one that completely describes your network neighborhood and knows how to get to the routers for other neighborhoods on the Internet.
Your packet may pass through several routers on the way to its destination. Routers are smart. They watch how long it takes for other routers to acknowledge having received a packet. They also use that information to direct traffic over fast links. They use it to notice when another router (or a cable) have dropped off the network, and compensate if possible by finding another route.
There's an urban legend that the Internet was designed to survive nuclear war. This is not true, but the Internet's design is extremely good at getting reliable performance out of flaky hardware in an uncertain world. This is directly due to the fact that its intelligence is distributed through thousands of routers rather than concentrated in a few massive and vulnerable switches (like the phone network). This means that failures tend to be well localized and the network can route around them.
Once your packet gets to its destination machine, that machine uses the service number to feed the packet to the web server. The web server can tell where to reply to by looking at the command packet's source IP address. When the web server returns this document, it will be broken up into a number of packets. The size of the packets will vary according to the transmission media in the network and the type of service.

1.4. TCP and IP

To understand how multiple-packet transmissions are handled, you need to know that the Internet actually uses two protocols, stacked one on top of the other.
The lower level, IP (Internet Protocol), is responsible for labeling individual packets with the source address and destination address of two computers exchanging information over a network. For example, when you access http://ravivini.blogspot.com, the packets you send will have your computer's IP address, such as 192.168.1.101, and the IP address of the ravivini.blogspot.com computer, 152.2.210.81. These addresses work in much the same way that your home address works when someone sends you a letter. The post office can read the address and determine where you are and how best to route the letter to you, much like a router does for Internet traffic.
The upper level, TCP (Transmission Control Protocol), gives you reliability. When two machines negotiate a TCP connection (which they do using IP), the receiver knows to send acknowledgements of the packets it sees back to the sender. If the sender doesn't see an acknowledgement for a packet within some timeout period, it resends that packet. Furthermore, the sender gives each TCP packet a sequence number, which the receiver can use to reassemble packets in case they show up out of order. (This can easily happen if network links go up or down during a connection.)
TCP/IP packets also contain a checksum to enable detection of data corrupted by bad links. (The checksum is computed from the rest of the packet in such a way that if either the rest of the packet or the checksum is corrupted, redoing the computation and comparing is very likely to indicate an error.) So, from the point of view of anyone using TCP/IP and nameservers, it looks like a reliable way to pass streams of bytes between hostname/service-number pairs. People who write network protocols almost never have to think about all the packetizing, packet reassembly, error checking, checksumming, and retransmission that goes on below that level.

1.5. HTTP, an application protocol

Now let's get back to our example. Web browsers and servers speak an application protocol that runs on top of TCP/IP, using it simply as a way to pass strings of bytes back and forth. This protocol is called HTTP (Hyper-Text Transfer Protocol) and we've already seen one command in it — the GET shown above.
When the GET command goes to ravivini.blogspot.com's webserver with service number 80, it will be dispatched to a server daemonlistening on port 80. Most Internet services are implemented by server daemons that do nothing but wait on ports, watching for and executing incoming commands.
If the design of the Internet has one overall rule, it's that all the parts should be as simple and human-accessible as possible. HTTP, and its relatives (like the Simple Mail Transfer Protocol, SMTP, that is used to move electronic mail between hosts) tend to use simple printable-text commands that end with a carriage-return/line feed.
This is marginally inefficient; in some circumstances you could get more speed by using a tightly-coded binary protocol. But experience has shown that the benefits of having commands be easy for human beings to describe and understand outweigh any marginal gain in efficiency that you might get at the cost of making things tricky and opaque.

Mpemba effect

The Mpemba effect is the observation that warmer water sometimes freezes faster than colder water. Although the observation has been verified, there is no single scientific explanation for the effect.
                         
Origin

The effect is named for Tanzanian Erasto Mpemba. He first encountered the phenomenon in 1963 in Form 3 of Magamba Secondary School, Tanganyika when freezing ice cream mix that was hot in cookery classes and noticing that they froze before cold mixes. After passing his O-level examinations, he became a student at Mkwawa Secondary (formerly High) School, Iringa, Tanzania. The headmaster invited Dr. Denis G. Osborne from the University College in Dar Es Salaam to give a lecture on physics. After the lecture, Erasto Mpemba asked him the question "If you take two similar containers with equal volumes of water, one at 35 °C (95 °F)and the other at 100 °C (212 °F), and put them into a freezer, the one that started at 100 °C (212 °F) freezes first. Why?" only to be ridiculed by his classmates and teacher. After initial consternation, Dr. Osborne experimented on the issue back at his workplace and confirmed Erasto's finding. They published the results together in 1969.

Causes

Osborne observed that the top is warmer than the bottom in a beaker of water being cooled, the difference being sustained by convection. Blocking heat transfer from the top with a film of oil drastically slowed cooling. Also, the effect of dissolved air was accounted for by using boiled water. The beakers were also insulated from the bottom.
At first sight, the behaviour seems contrary to thermodynamics. Many standard physical theory effects contribute to the phenomenon, although no single explanation is conclusive. Several effects may contribute to the observation, depending on the experimental set-up:
  • Definition of frozen: Is it the physical definition of the point at which water forms a visible surface layer of ice, or the point at which the entire volume of water becomes a solid block of ice? Some experiments have instead measured the time until the water reached 0°C.
  • Evaporation: The evaporation of the warmer water reduces the mass of the water to be frozen. Evaporation is endothermic, meaning that the water mass is cooled by vapor carrying away the heat, but this alone probably does not account for the entirety of the effect.
  • Convection: Accelerating heat transfers. Reduction of water density below 4 °C (39 °F) tends to suppress the convection currents that cool the lower part of the liquid mass; the lower density of hot water would reduce this effect, perhaps sustaining the more rapid initial cooling. Higher convection in the warmer water may also spread ice crystals around faster.
  • Frost: Has insulating effects. The lower temperature water will tend to freeze from the top, reducing further heat loss by radiation and air convection, while the warmer water will tend to freeze from the bottom and sides because of water convection. This is disputed as there are experiments that account for this factor.
  • Supercooling: It is hypothesized that cold water, when placed in a freezing environment, supercools more than hot water in the same environment, thus solidifying slower than hot water.[9] However, supercooling tends to be less significant where there are particles that act as nuclei for ice crystals, thus precipitating rapid freezing.
  • Solutes: The effects of calcium,magnesium carbonate among others.[10]
  • The effect of heating on dissolved gases; however, this was accounted for in the original article by using boiled water.


Wednesday, August 17, 2011

How does a gas lighter work? Part-2


                                                             Part-2

Converting Mechanical Vibration into Electricity
Some Fine Ceramics (also known as “advanced ceramics”) possess a unique property allowing them to convert mechanical shock or vibration into electrical signals, and vice versa. These materials, called piezoelectric ceramics, are built into a wide variety of products. One example is the stovetop burner used in a typical kitchen gas range that is ignited by converting mechanical shock into an electrical arc that lights the gas. The clicking noise you hear when you turn the control dial is the sound of a piezoelectric ceramic being struck to induce the necessary mechanical shock. Some lighters also use this mechanism.
Applications: Piezoelectric ignition units designed to light gas burners.



How does a gas lighter work?



                                                                       \Part-1

Piezoelectricity [Basic Principles Of GAS-LIGHTER ]
Piezoelectric materials exhibit both a direct and a reverse piezoelectric effect. The direct effect produces an electrical charge when a mechanical vibration or shock is applied to the material, while the reverse effect creates a mechanical vibration or shock when electricity is applied.

Piezoelectric substances are polycrystalline materials consisting of lead zirconate titanate, or PZT. Lead (Pb), zirconium (Zr) and titanium (Ti) are combined with additives to achieve desired levels of performance. A PZT component possesses the unique ability to generate vibrations based on its shape when electricity is applied, and to generate electricity upon exposure to mechanical vibration or shock.


Second from Disaster


Saturday, August 6, 2011

"क्या सलवा जुडूम का अंत मीडिया के अंधा धुँध प्रचार का कारनामा है?

     



क्या आप जानते हैं ? किस भारतीय पीएम को “निशान ए पाकिस्तान” मिला?






दिग्विजय सिंह गद्दारों का वंशज :ह्त्या का आरोपी !!

मनुष्य को जैसे संस्कार अपने पुरखों से मिलते हैं ,उसके अनुरूप ही उसका स्वभाव ,चरित्र और विचार बन जाते हैं .यह एक निर्विवाद सत्य है .और दिग्विजय के ऊपर पूरी तरह से लागू होती है .दिग्विजय खुद को प्रथ्वी राज चौहान का वंशज बताता है .लेकिन इसका कोई प्रमाण नहीं मिलता है .दिग्विजय क्षत्रिओं की एक उपजाति "खीची "से सम्बंधित है .इसका विवरण "खीची इतिहास संग्रह "में मिलता है .इसके लेखक A .H .Nizami और G .S .Khichi है .पुस्तक का संपादन R .P .Purohit ने किया है .किताब "खिची शोध संस्थान जोधपुर "से प्रकाशित हुई थी .एक और पुस्तक "Survay of khichii History "में खीचियों के बारे में जानकारी मिलती है .खिची धन लेकर किसी राजा के लिए युद्ध करते थे .आज दिग्विजय खुद को मध्य प्रदेश में गुना जिला के एक छोटी सी रियासत "राघोगढ़ "का राजा कहता है .उसके चमचे उसे दिग्गी राजा पुकारते है .


1 -दिग्विजय का पूर्वज कौन था
पुस्तक के अनुसार दिग्विजय के हाथों जो रियासत मिली एक "गरीब दास "नामके सैनिक को अकबर ने दी थी .जब राजपुताना और मालवा के सभी क्षत्रिय राणा प्रताप के साथ हो रहे थे .गरीब दास अकबर के पास चला गया .अकबर ने उसकी सेवा से प्रसन्न होकर मालवा के सूबेदार को हुक्म भेजा की गरीब दास को एक परगना यानि पांच गाँव दे दिए जाएँ . गरीब दास की मौत के बाद उसके पुत्र "बलवंत सिंह (1770 -1797 ) ने इसवी 1777 में बसंत पंचमी के दिन एक गढ़ी की नींव रखी और उसका नाम अपने कुल देवता "राघोजी "के नाम पर "राघोगढ़ "रख दिया था .
कर्नल टाड के इतिहास के अनुसार बलवंत सिंह ने 1797 तक राज किया .और अंगरेजों से दोस्ती बढ़ाई.जब सन 1778 में प्रथम मराठा युद्ध हुआ तो बलवंत सिंह ने अंगरेजी फ़ौज की मदद की थी
इसका उल्लेख जनरल Gadred ने "Section from State Papers .Maratha Volume I Page 204 में किया है .बलवंत सिंह की इस सेवा के बदले कम्पनी सरकार ने Captain fielding की तरफ से बलदेव सिंह को पत्र भेजा ,जिसमे लिखा था कंपनी बहादुर की तरफ से यह परगना जो बालामेटमें है उसका किला राघोगढ़ तुम्हें प्रदान किया जाता है और उसके साथ के गावों को अपना राज्य समझो .यदि सिंधिया सरकार किसी प्रकार का दखल करे तो इसकी सूचना मुझे दो ..
बाद में जब 1818 में बलवंत सिंह का नाती अजीत सिंह (1818 -1857 )गद्दी पर बैठा तो अंगरेजों के प्रति विद्रोह होने लगे था ,अजीत सिंह ने ग्वालियर के रेजिडेंट को पत्र भेजा कि,आजकल महाराज सिंधिया बगावत की तय्यारी कर रहे हैं .उनके साथ झाँसी और दूसरी रियासत के राजा भी बगावत का झंडा खड़ा कर रहे हैं .इसलिए इन बागियों को सजा देने के लिए जल्दी से अंगरेजी फ़ौज भेजिए ,उस पत्र का जवाब गवालियर के रेजिडेंट A .Sepoyrs ने इस तरह दिया "आप कंपनी की फ़ौज की मदद करो और बागियों साथ नहीं दो .आप हमारे दोस्त हो ,अगर सिंधिया फ़ौज येतो उस से युद्ध करो .कंपनी की फ़ौज निकल चुकी है .
लेकिन सन 1856 में एक दुर्घटना में अजीत सिघ की मौत हो गयी .उसके बाद 1857 में उसका लड़का "जय मंगल सिंह "(1857 -1900 )गद्दी पर बैठा इसके बाद "विक्रमजीत सिंह राजा बना (1900 -1902 (.लेकिन अंग्रेज किसी कारण से उस से नाराज हो गए .और उसे गद्दी से उतार सिरोंज परिवार के एक युवक "मदरूप सिंह "को राजा बना दिया जिसका नाम "बहादुर सिंह "रख दिया गया ( 1902 -1945 )अंगरेजों की इस मेहरबानी के लिए बहादुर सिंह ने अंगरेजी सरकार का धन्यवाद दिया और कहा मैं वाइसराय का आभारी हूँ .मैं वादा करता हूँ कि सरकार का वफादार रहूँगा .मेरी यही इच्छा है कि अंगरेजी सरकार के लिए लड़ते हुए ही मेरी जान निकल जाये .
इसी अंगरेज भक्त गद्दार का लड़का "बलभद्र सिंह "हुआ जो दिग्विजय का बाप है .बलभद्र का जन्म 1914 में हुआ था और इसके बेटे दिग्विजय का जन्म 28 फरवरी 1947 को इन्दौर में हुआ था .
बलभद्र सिंह ने मध्य भारत (पूर्व मध्य प्रदेश )की विधान सभा का चुनाव हिन्दू महा सभा की सिट से लड़ा था .और कांग्रेस के उम्मीदवार जादव को हराया था .सन 1969 में दिग्विजय ने भी नगर पालिका चुनाव कांग्रेस के विरुद्ध लड़ा था .और जीत कर अध्यक्ष बन गया था .
लेकिन इमरजेंसी के दौरान गिरफ्तारी से बचने लिए जब दिग्विजय अपने समाधी "अर्जुन सिघ "के पास गया तो उसने कांग्रस में आने की सलाह दी .और कहा यदि जागीर बचाना है तो कांग्रेस में आ जाओ .
इस तरह दिग्विजय का पूरा वंश अवसरवाद ,खुशामद खोरी .और अंगरेजों सेवा करने लगा है
इसी कारण से जब दिग्विजय उज्जैन गया था तो वहां के भाजयुमो के अध्यक्ष "धनञ्जय शर्मा "ने सबके सामने गद्दार करार दिया था .ओर सबूत के लिए एक सी डी बी पत्रकारों को बांटी थी (पत्रिका शुक्रवार 22 जुलाई 2011 भोपाल )

2 -दिग्विजय ने कांग्रेसी नेत्री की हत्या करवायी !
अभी तक अधिकांश लोग इस बात का रहस्य नहीं समझ पा रहे थे कि दिग्विजय R .S .S और हिदुओं से क्यों चिढ़ता है .अभी अभी इसका कारण पता चला है .यद्यपि यह घटना पुरानी है .इसके अनुसार 14 फरवरी 1997 को रत के करीब 11 बजे दिग्विजय उसके भी लक्ष्मण सिंह और कुछ दुसरे लोगों ने "सरला मिश्रा "नामकी एक कांग्रेसी नेत्री की कोई ज्वलन शील पदार्थ डाल कर हत्या कर दी थी .और महिला को उसी हालत में जलता छोड़कर भाग गए थे .इतने समय के बाद यह मामला समाज सेवी और बी जे पी के पूर्व पार्षद महेश गर्ग ने फिर अदालत में पहुंचा दिया है और सी .जे .एम् श्री आर .जी सिंह के समक्ष ,दिग्विजय सिंह ,उसके भाई लक्षमण सिंह ,तत्कालीन टी आई एस.एम् जैदी ,नायब तहसीलदार आर .के.तोमर ,तहसीलदार डी.के. सत्पथी ,डा .योगीराज शर्मा .ऍफ़.एस.एल के यूनिट प्रभारी हर्ष शर्मा और नौकर सुभाष के खिलाफ भारतीय दंड संहिता की धारा 302 ,201 .212 ,218 ,120 बी ,और 461 अधीन मामला दर्ज करने के आदेश देने के लिए आवेदन कर दिया है .फरियादी महेश गर्ग ने धारा 156 .3 यह भी निवेदन भी किया है कि उक्त सभी आरोपियों के विरुद्ध जल्दी कार्यवाही कि जाये .इसपर सी. जे. एम् महोदय ने सुनवाई की तारीख 28 जुलाई तय कर दी है .यही कारण है कि दिग्विजय सभी हिन्दुओं का गालियाँ देता है (दैनिक जागरण 23 जुलाई 2011 भोपाल )
हम सब जानते है कि आपसी विवाह सम्बन्ध करते समय परिवार का खानदान देखा जाता है .नियोजक किसी को नौकरी देते समय आवेदक की पारिवारिक पृष्ठभूमि देख लेते है .यहांतक जानवरों की भी नस्ल देखी जाती है .
फिर गद्दारों की संतान गद्दार देश भक्त कैसे हो सकते हैं .विदेशी अंगरेजों के चमचे विदेशी सोनिया चमचागिरी क्यों न करेगा .ऐसा व्यक्ति कुत्ते से भी बदतर है ,कुत्ता अपनो को नहीं काटता है .इसने तो कांग्रेसी महिला नेत्री की निर्दयता पूर्वक हत्या करा दी .