Mac Address To Ipv4 Converter

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Aug 22, 2010 You can also find out if the MAC address is from a switch or other networking device from HP, CISCO, etc. If you're sure the MAC address is a computer, then try the methods below to determine the IP address. Method 1 – DHCP Server. The simplest way to get an IP address from a MAC address is to check out the DHCP server, if possible. Search by Ethernet MAC address, OUI, or Bluetooth device address: Enter complete MAC address or at least first six characters including all leading zeros. For example: 00-16-68 or 00-16-68-2B-40-90 or 00:16:68:2B:40:90 or 00 or 00.16.68.2B.40.90. This is the most common notation for IPv4 addresses. Each address is 32 bits in length and the 32-bit address is broken up into four 8-bit octets. Examples include 192.0.2.0, 198.51.100.0, and 203.0.113.0. IPv6 addresses are 128-bits in length. Convert a mac address between integer, hexadecimal, dot notation and more IPv4 Converter Convert IP addresses to decimal format, integer format, and more!

How to find an IP address when you have the MAC address of the device.

4 Steps total

Step 1: Open the command prompt

Click the Windows 'Start' button and select 'Run.' In the textbox, type 'cmd' and click the 'Ok' button. This opens a DOS prompt.

Step 2: Familiarize yourself with arp

Type 'arp' in the command prompt. This gives you a list of options to use with the arp command.

Step 3: List all MAC addresses

Type 'arp -a' in the command prompt. This lists a number of MAC addresses with the associated IP addresses. Since you have the MAC address, scroll down the list to find the associated IP address. The MAC address is shown in the 'Physical Address' column with the IP address in the 'Internet Address' column. An example of a table record is in Step 4.

Step 4: Evaluate results

The following is an example of ARP output. The first column is the IP address. The second column is the MAC address, and the third is the type of IP assigned--static or dynamic.

Internet address Physical Address Type

192.168.0.1 01-a3-56-b5-ff-22 static

References

• How to Use a MAC Address to Find an IP Address

16 Comments

• Datil
  Krizz Jan 21, 2013 at 10:36pm

  You've forgotten about one little thing: arp keeps mac<>ip association of recently contacted peers, so it's quite often not to find the mac<>ip association we're looking for, of machine that exists in the network. Prior to using arp -a it's wise to ping the host first.

• Habanero
  Twon of An Jan 21, 2013 at 11:24pm

  Used in conjunction with ping (thanks Krizz), this is a good basic walk through. I can't go wrong with these steps!

• Cayenne
  Syldra Jan 22, 2013 at 03:17pm

  I'm sorry but... if the thing is to find the IP address from the MAC, how will you ping the host first ?

• Serrano
  Enzeder Jan 22, 2013 at 04:37pm

  I thought the aim of this exercise was to FIND an IP address. Doesn't using PING imply you already know the IP (or hostname) which makes ARP redundant? How do you PING a MAC?

  Assuming no IP or hostname info, I have used a portscanner (like LanSpy or Zenmap) to get MAC > IP info. Currently my preferred method if the device isn't listed in Spiceworks :-)

  There was a time when I was a baby admin and I didn't want to raise alarms by installing a scanner that I wrote a batch file (yes, that long ago) that PINGed every IP on a subnet, then immediately ran ARP redirecting output to a text file. But that depends on the device in question being set to respond to PING requests.

• Pimiento
  christian.mcghee Dec 23, 2013 at 03:47am

  This does not work for any host on the other side of a router. Any hosts on the other side of the router will show the routers MAC address.

• Serrano
  @Greg Mar 11, 2014 at 03:11pm

  I realize this is an old topic, but someone like myself may be looking for an answer. I became admin of a network with little over 200 devices, which none of the cabling was mapped. I was told I was responsible for the cabling, so I began looking for a way other than toning out all the cables. I was fortunate to have Cisco switches and Windows Server 2008. I was able to use the Cisco Network Assistant to grab MAC addresses and the port number, then in DHCP on the Server 2008 I could find the MAC and corresponding IP. Furthermore I could also get the computer name from DHCP and correlate that to which user was on the machine using PDQ inventory to see who was logged in to the machine. Most of this of course depends on the devices being in use. I've been able to create an accurate map of about 90% of my network without touching the cables.

• Pimiento
  christopherblouch Jun 4, 2014 at 05:08pm

  I am interested in this thread, hopefully someone can help. There are 4 types of arp message: arp request, arp reply, rarp request, rarp reply. So, that being said, is it possible to manually send a rarp request? Sort of a arp based ping?There is arping, but we need rarping... if it exists. Of course, I understand that I can't arp outside my default gateway, but if there is a rarp request, how is it used inside the local network? Thanks to whatever guru can explain what we're missing.

• Serrano
  Maxwell Brotherwood Jul 18, 2014 at 10:07am

  Great for finding an IP if you have the MAC address.

  My instance where I found this useful was after updating the firmware on a switch remotely via TFTP, the IP of the switch would change (making pinging redundant, obviously). Trying a network scan over Spiceworks or rescanning the single device would not update the IP and I needed an alternate way to find it.

  This method worked perfectly. Thank you. Hopefully this helps those trying to understand the purpose of this practice and how it was in-fact useful.

• Pimiento
  robertrobinson2 Aug 4, 2014 at 04:30pm

  I understand the issues in attempting to use a MAC address to locate a device from outside of its local network.
  What puzzles me is how Honeywell Total Connect does this with their WiFi connected thermostats. The hardware configuration is: a Honeywell WiFi thermostat that is WiFi connected to a Netgear N600 router which uses DHCP to assign an IP adddress. The router is connected to Comcast with a Motorola SB6120 modem. Comcast assigns a system wide (dynamic) IP. There is no static IP.
  On initial setup, a WiFi connection is first established between the thermostat and the router. The thermostat's MAC and CRC and a username and password are entered into the Total Connect software setup. It is then possible to read or set thermostat values using Total Connect Web pages.
  I know how to do this with a static IP or a DNS service that automatically tracks changes in dynamic IP addresses.
  Does anyone understand how this works with Total Connect?

• Tabasco
  Joe979 Sep 4, 2014 at 01:05pm

  This post was extremely helpful, thanks itdownsouth :) I used show interface to find MAC addresses on our switches (reason for this is poor network documentation and mis-labeled switchports and wall jacks...). I took the MAC addresses that I could not locate the hosts or ip addresses for, ran arp -a to list the address<>mac list, then one by one, nbtstat -A for each IP address I matched a MAC to from the unlabeled ports. Tedious, but found 5 or 6 now (seeing hexadecimal thoughts now though...).

• Tabasco
  Joe979 Sep 4, 2014 at 01:12pm

  By the way, the reason this is working great for me is the lack of routers -- all switches, so if you have only one subnet like we do, this will do -- otherwise, you will probably need to login to the router or switch on the other side of the router to find MAC address tables on the other networks. You may not be able to see them all on the local host, as far as arp -a on the local host, but looking up the arp or hosts tables on switches and routers could be a possible solution for those with multiple subnets.

• Jalapeno
  Jay196 Oct 21, 2014 at 03:28pm

  Use SuperScan to do a bulk ping of the entire network range. SuperScan 3 (I recommend) is a free tool by McAfee.

  Then use arp -a | Find '5c-d9-98' to get for example all ping nodes with a manufacturer of Asus.

• Datil
  WealthyEmu Mar 25, 2015 at 07:55pm

  There's also this:

  http://www.advanced-ip-scanner.com/

  It should be able to find most devices on the network. You can specify the range to scan and scan across subnets. I won't try to share all the features because quite frankly I don't know them all.

• Pimiento
  amiruli Jul 4, 2015 at 10:18am

  If you want you can ping the broadcast address to ping everyone on the network then do arp -a

• Pimiento
  chrisdahlkvist Nov 23, 2015 at 09:56am

  @RobertRobinson I'm the lead designer and project manager on the Honeywell systems.

  I can tell you exactly how I designed it. It's actually quite simple. Nothing is sent back to the unit. The unit is allowed access to the Internet via your setup and the router. As long as the unit has permission to make an outbound connection it will work. What happens is the unit makes a report to the server. If it needs to make a request then it gives the server a unique key. The server puts any needed data in an xml (readable) and the thermostat (or quite a few other devices) hits that URL a few seconds later (the device told the server where it would pick up that info).

  All your device needs is a simple read-only connection to the outside world. No need to download anything.
  It's a VERY simple process that I developed back in 1992 when the Interwebs were still pretty new to most people. There were many processes built off of this simple idea (it was pretty cutting edge when I first designed it). Store and forward, offline browsing, push technology, etc. all are based on this simple technology.

  Am I rich? Not even close. I was working on my PhD at the time and was hired by Honeywell to implement my design. I literally gave it away to the general public as is right.

  I hope that clears it up for you. If not, feel free to contact me for more information.

  Chris Dahlkvist
  chris@usarf.org

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Ethernet MAC Address (7.2)

Ethernet technology relies on MAC addresses to function. MAC addresses are used to identify the frame source and destination.

MAC Address and Hexadecimal (7.2.1)

As discussed in detail in Chapter 5, 'Number Systems,' in networking, IPv4 addresses are represented using the decimal (base 10) number system and the binary (base 2) number system. IPv6 addresses and Ethernet addresses are represented using the hexadecimal (base 16) number system. To understand hexadecimal, you must first be very familiar with binary and decimal.

The hexadecimal numbering system uses the numbers 0 to 9 and the letters A to F.

An Ethernet MAC address consists of a 48-bit binary value. Hexadecimal is used to identify an Ethernet address because a single hexadecimal digit represents 4 binary bits. Therefore, a 48-bit Ethernet MAC address can be expressed using only 12 hexadecimal values.

Figure 7-5 compares the equivalent decimal and hexadecimal values for binary 0000 to 1111.

Figure 7-5 Decimal to Binary to Hexadecimal Conversion

Given that 8 bits (1 byte) is a common binary grouping, binary 00000000 to 11111111 can be represented in hexadecimal as the range 00 to FF, as shown in the Figure 7-6.

Figure 7-6 Selected Examples of Decimal to Binary to Hexadecimal Conversions

When using hexadecimal, leading zeros are always displayed to complete the 8-bit representation. For example, in Figure 7-6, the binary value 0000 1010 is shown to be 0A in hexadecimal.

Hexadecimal numbers are often represented by a value preceded by 0x (for example, 0x73) to distinguish between decimal and hexadecimal values in documentation.

Hexadecimal may also be represented using a subscript 16 or by using the hex number followed by an H (for example, 73H).

You might have to convert between decimal and hexadecimal values. If such conversions are required, convert the decimal or hexadecimal value to binary and then to convert the binary value to either decimal or hexadecimal as appropriate. See Chapter 5 for more information.

Ethernet MAC Address (7.2.2)

In an Ethernet LAN, every network device is connected to the same shared medium. The MAC address is used to identify the physical source and destination devices (NICs) on the local network segment. MAC addressing provides a method for device identification at the data link layer of the OSI model.

An Ethernet MAC address is a 48-bit address expressed using 12 hexadecimal digits, as shown in Figure 7-7. Because 1 byte equals 8 bits, we can also say that a MAC address is 6 bytes in length.

Figure 7-7 Ethernet MAC Address in Bits, Hextets, and Bytes

All MAC addresses must be unique to the Ethernet device or Ethernet interface. To ensure uniqueness, every vendor that sells Ethernet devices must register with the IEEE to obtain a unique 6-digit hexadecimal (that is, 24-bit or 3-byte) code called an organizationally unique identifier (OUI).

When a vendor assigns a MAC address to a device or to an Ethernet interface, the vendor must do as follows:

Mac Address To Ipv4 Converter File

• Use its assigned OUI as the first 6 hexadecimal digits.

• Assign a unique value in the last 6 hexadecimal digits.

Mac Address To Ipv4 Converter Tool

Therefore, an Ethernet MAC address consists of a 6-digit hexadecimal vendor OUI code followed by a 6-digit hexadecimal vendor-assigned value, as shown in Figure 7-8.

For example, say that Cisco needs to assign a unique MAC address to a new device, and the IEEE has assigned Cisco the OUI 00-60-2F. Cisco would configure the device with a unique vendor code such as 3A-07-BC. Therefore, the Ethernet MAC address of that device would be 00-60-2F-3A-07-BC.

It is the responsibility of a vendor to ensure that no two of its devices are assigned the same MAC address. However, it is possible for duplicate MAC addresses to exist because of mistakes made during manufacturing, mistakes made in some virtual machine implementation methods, or modifications made using one of several software tools. In such a case, it is necessary to modify the MAC address with a new NIC or make modifications by using software.

Frame Processing (7.2.3)

Sometimes a MAC address is referred to as a burned-in address (BIA) because the address is hard coded into read-only memory (ROM) on the NIC. This means that the address is permanently encoded into the ROM chip.

Mac Address To Ipv4

When the computer boots up, the NIC copies its MAC address from ROM into RAM. When a device is forwarding a message to an Ethernet network, as shown in Figure 7-9, the Ethernet header includes the following:

• Source MAC address: This is the MAC address of the source device NIC.

• Destination MAC address: This is the MAC address of the destination device NIC.

Figure 7-9 The Source Prepares a Frame to Send to the Destination

When a NIC receives an Ethernet frame, it examines the destination MAC address to see if it matches the physical MAC address that is stored in RAM. If there is no match, the device discards the frame. In Figure 7-10, H2 and H4 discard the frame. The MAC address matches for H4, so H4 passes the frame up the OSI layers, where the de-encapsulation process takes place.

Figure 7-10 All Devices Receive the Frame, but Only the Destination Processes It

Any device that is the source or destination of an Ethernet frame will have an Ethernet NIC and, therefore, a MAC address. This includes workstations, servers, printers, mobile devices, and routers.

Unicast MAC Address (7.2.4)

In Ethernet, different MAC addresses are used for Layer 2 unicast, broadcast, and multicast communications.

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A unicast MAC address is a unique address that is used when a frame is sent from a single transmitting device to a single destination device.

In Figure 7-11, the destination MAC address and the destination IP address are both unicast.

A host with IPv4 address 192.168.1.5 (source) requests a web page from the server at IPv4 unicast address 192.168.1.200. For a unicast packet to be sent and received, a destination IP address must be in the IP packet header. A corresponding destination MAC address must also be present in the Ethernet frame header. The IP address and MAC address combine to deliver data to one specific destination host.

The process that a source host uses to determine the destination MAC address associated with an IPv4 address is known as Address Resolution Protocol (ARP). The process that a source host uses to determine the destination MAC address associated with an IPv6 address is known as Neighbor Discovery (ND).

Broadcast MAC Address (7.2.5)

An Ethernet broadcast frame is received and processed by every device on an Ethernet LAN. The features of an Ethernet broadcast are as follows:

• It has the destination MAC address FF-FF-FF-FF-FF-FF in hexadecimal (or 48 1s in binary).

• It is flooded out all Ethernet switch ports except the incoming port.

• It is not forwarded by a router.

If the encapsulated data is an IPv4 broadcast packet, this means the packet contains a destination IPv4 address that has all 1s in the host portion. This numbering in the address means that all hosts on that local network (broadcast domain) receive and process the packet.

In Figure 7-12, the destination MAC address and destination IP address are both broadcast addresses.

Figure 7-12 Broadcast Frame Transmission

The source host sends an IPv4 broadcast packet to all devices on its network. The IPv4 destination address is a broadcast address, 192.168.1.255. When the IPv4 broadcast packet is encapsulated in the Ethernet frame, the destination MAC address is the broadcast MAC address FF-FF-FF-FF-FF-FF in hexadecimal (or 48 1s in binary).

DHCP for IPv4 is an example of a protocol that uses Ethernet and IPv4 broadcast addresses. However, not all Ethernet broadcasts carry IPv4 broadcast packets. For example, ARP requests do not use IPv4, but the ARP message is sent as an Ethernet broadcast.

Multicast MAC Address (7.2.6)

An Ethernet multicast frame is received and processed by a group of devices on the Ethernet LAN that belong to the same multicast group. The features of an Ethernet multicast frame are as follows:

• It has destination MAC address 01-00-5E when the encapsulated data is an IPv4 multicast packet and destination MAC address 33-33 when the encapsulated data is an IPv6 multicast packet.

• There are other reserved multicast destination MAC addresses for when the encapsulated data is not IP, such as Spanning Tree Protocol (STP) and Link Layer Discovery Protocol (LLDP).

• It is flooded out all Ethernet switch ports except the incoming port, unless the switch is configured for multicast snooping.

• It is not forwarded by a router unless the router is configured to route multicast packets.

If the encapsulated data is an IP multicast packet, the devices that belong to a multicast group are assigned a multicast group IP address. The range of IPv4 multicast addresses is 224.0.0.0 to 239.257.257.257. The range of IPv6 multicast addresses begins with ff00::/8. Because a multicast address represents a group of addresses (sometimes called a host group), it can only be used as the destination of a packet. The source is always a unicast address.

As with the unicast and broadcast addresses, a multicast IP address requires a corresponding multicast MAC address to deliver frames on a local network. The multicast MAC address is associated with, and uses addressing information from, the IPv4 or IPv6 multicast address.

In Figure 7-13, the destination MAC address and destination IP address are both multicast addresses.

Mac Address To Ipv4 Converter Download

Routing protocols and other network protocols use multicast addressing. Applications such as video and imaging software may also use multicast addressing, although multicast applications are not as common.