Bitcoin Wallet Transaction Alerts notify you by email when a bitcoin address has activity on the blockchain ; View, monitor and search bitcoin ownership and wallet balance by name, bitcoin address, email address, url or keyword; Check a BTC address to find connected websites or owner profiles! Dec 24, · You can view your change address for any given outgoing transaction by clicking on your transaction history. Then, expand the specific transaction to view extra details. Of course, there are times when your transaction may not need a change address. Instead of sending your leftover BTC (that you didn't want to send inside your transaction) back to the same address, your wallet automatically sends it to a different change address that is also part of your Bitcoin wallet. The leftover change does not ever leave your Bitcoin wallet but it moves to a .
Btc address changedBitcoin Address Lookup, Checker and Scam Reports - BitcoinWhosWho
Then, expand the specific transaction to view extra details. Of course, there are times when your transaction may not need a change address. To sum all of this up, change addresses are an aspect of cryptocurrency that allow users to transact using exact amounts, even if the transaction isn't the total amount of the output being spent.
It's similar to when people transact with cash. In cryptocurrency, the difference between the total amount paid and the total transaction cost is sent back to the user as change using a change address. Still have questions about change addresses? Let us know by submitting them here.
Facebook Twitter LinkedIn. Have more questions? A more detailed explanation may be helpful when reading this article. Imagine that Alice, who controls an address containing one unspent output worth 10 bitcoin BTC , wants to pay Bob 10 bitcoin. After the transaction, Bob can give the unspent output he received from Alice to someone else.
However, Alice will neither be allowed to take back the unspent output she transferred, nor will she be able to spend it again.
To resolve this dilemma, Alice uses a transaction that splits her payment, a feature fully supported by Bitcoin. In the previous examples, Alice directed change into the same address she spent from. Any observer capable of linking Bitcoin addresses to personal identities can begin to draw conclusions about money transfers between people.
Users make this job more difficult by sending change to newly-created addresses. To see why, imagine a transaction that sends funds from Address A to Address B.
If change is returned to Address A, the block chain reveals that the person controlling Address A paid the person controlling Address B. The same reasoning holds if two or more addresses are involved. Any transaction involving Address A as a sender reveals the receiving address unambiguously. Should the identity of the person controlling either receiving or payment addresses become known, the identities of the other parties could become known as well.
Now imagine that Address A initiates a payment to B, but this time directs change to a newly-generated change address C. The identity of the person controlling Addresses B or C may or may not be the same as the identity of the person controlling Address A. Given another transaction from Address C, the picture becomes even murkier.
Which of the transfers represent payments and which represent the receipt of change? An observer trying to link personal identities to addresses must gather more secondary information and expend more resources when all parties send change to newly-created addresses. Coordinating multiple addresses is a complicated task. Wallet software frees the user from the need to do this manually. Although change addresses play a key role in improving privacy, wallet developers can implement this feature in a number of ways.
Four strategies are currently in use, each with its own implications for privacy and security. Incorrect use of Bitcoin change addresses account for many cases of loss or theft of funds. Here are some disaster scenarios and ways to avoid them. Alice uses an old version of Bitcoin-Qt. Understanding the importance of backups, she created an encrypted wallet backup long ago and stored it in a safe place. Alice bought a new hard drive and then re-installed Bitcoin-Qt on it.
She then restored her wallet backup. To her horror, Alice discovered the restored wallet was empty. Explanation: Alice generated enough change addresses to overflow the original pool of Restoring the backup only restored empty addresses. Using data recovery tools, Alice may be able to salvage the Bitcoin-Qt wallet from the faulty hard drive, and with it her lost funds. Bob uses Electrum to send infrequent bitcoin payments. Worried about possible theft, he wanted a way to keep an eye on his bitcoin balance from one of his many devices.
Bob decided on blockchain. A few weeks later, Bob made a 0. After receiving his merchandise, Bob decided to check his balance with blockchain. Disturbingly, Bob discovered that part of his Overstock payment was transferred to an unknown address. Thinking that his computer running Electrum had been compromised, Bob re-formated the hard drive.
This cleared the balance from the sending address, the only one Bob was monitoring. Recovery: Electrum encourages the storage of its word address generation seed in a safe location. Should Bob still have access to the seed, he can re-generate his old wallet and recover the change from the Overstock transaction. Carlos is a saver. One day Carlos noticed a deal on new laptops at Overstock and decided to pay using one of his saved bitcoins. But Carlos had a problem: he needed to get his paper wallet into a software wallet to pay Overstock.
After paying Overstock, he exited the program. Carlos was worried about leaving any trace of his private key on his computer, so he securely deleted MultiBit and its data directory. He then returned his paper wallet to its safe location. To his shock, the balance read zero. Nineteen bitcoins were sent to an unfamiliar address on the same day as the Overstock payment. The 19 missing bitcoins were sent to a change address, leaving his paper wallet empty.
Recovery: In securely deleting the MultiBit data directory, Carlos lost any chance of recovering the missing funds. Dave runs Bitcoin-Qt on two computers, a laptop and a desktop in his garage. Wanting to use both computers to make payments, Dave copied a clean wallet. After making many payments without a problem from both computers, Dave noticed something odd one day.
His laptop wallet showed a zero balance, but his desktop wallet showed the correct balance. Instead, his copy of Bitcoin-Qt running on the desktop used the last available pool address held jointly with the laptop.
Recovery: Back up the wallets on both the laptop and the desktop. Export all private keys from both computers, and sweep them into a new wallet. Frank received a paper wallet containing 2 BTC as a gift at a company event. Not seeing a need to keep the paper wallet, Frank threw it into the recycling bin at his office.
Over time, Frank depleted his Bitcoin funds. Shortly thereafter, Frank bought a set of sheets from Overstock for 0. Although this payment confirmed without issue, Frank noticed something odd. Without his approval, a second withdrawal was made to an unknown address, emptying his wallet of the remaining 1.
Explanation: Although Frank was the victim of theft, the route of attack was not his computer or network. It was the paper wallet he threw into the recycling bin. Unknown to Frank, the paper wallet was taken from the recycling bin by Eve, a dishonest coworker. Eve added the private key to a custom program that automatically detects deposits into a list of watched addresses, and then withdraws them immediately.
MultiBit, working as designed, used the imported paper wallet address to receive 1. Recovery: Frank cannot recover the funds, nor is he likely to determine the identity of the thief. Although the examples in the previous section resulted in complete loss of funds, the same mechanisms also allow for partial loss.
These conditions were assumed, which may or may not hold at the time a change address problem arises:. For example, a single address that receives multiple payments will contain multiple unspent outputs. Likewise, wallet balances can become distributed across multiple change addresses as the user spends funds.
As expected, her wallet balance decreases to 9 BTC. After installing a new hard drive and restoring her wallet backup, Alice notices something odd. Before the hard drive crash, her wallet balance was 9 BTC.
But the balance only read 8 BTC after recovering the backup. Why does 1 BTC seem to be missing? Alice was using a random address pool wallet, in which Address 2 was not contained in her original backup. In a sense, Alice was lucky because she could have lost her entire wallet balance. On the other hand, without understanding change addresses, Alice would likely be very confused about what happened to the missing 1 BTC.