Smart card wallet: Difference between revisions
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*Computers and smartphones are target for malware. The software on a smart card can be protected. | *Computers and smartphones are target for malware. The software on a smart card can be protected. | ||
*Smart cards do not need a battery, nor internet connection, they are robust. | *Smart cards do not need a battery, nor internet connection, they are robust. | ||
*Adoption: people are already used to | *Adoption: people are already used to paying with smart cards. | ||
===Desired features=== | ===Desired features=== | ||
Revision as of 14:05, 4 November 2011
This pages gathers resources for the implementation of a Bitcoin wallet on a smart card.
Rationale
- Computers and smartphones are target for malware. The software on a smart card can be protected.
- Smart cards do not need a battery, nor internet connection, they are robust.
- Adoption: people are already used to paying with smart cards.
Desired features
- no blockchain, no node; the card contains only private keys, and an algorithm to sign a transaction
- the smart card should have its own keyboard (for pin code protection) and display (to show the transaction amount)
- the card should implement a deterministic wallet, so that funds can be recovered if the card is lost.
Usage scenario
- the reading device may belong to a merchant at a point of sale; it cannot be trusted with private keys.
- the reading device is connected to a full bitcoin node; it can be trusted for getting and sending blockchain information.
- the reading device sends to the card the current balance of its bitcoin addresses. This information can be cached in the card.
- the reading device sends a bitcoin receiving address and transaction amount to the card.
- the amount is displayed by the card ; the user confirms the transaction with his pin code.
- the smart card creates a signed transaction and sends it to the reading device
- the transaction is checked and broadcast by the bitcoin node.
Implementation steps
1. write a bitcoin daemon that can talk to a lightweight wallet
- this has been done already, see for example bitcoinjs: https://github.com/bitcoinjs/bitcoinjs-lib
- See also this pull request: importexporttx can be used to broadcast the transaction
- https://bitcointalk.org/index.php?topic=28278.msg383312#msg383312
2. write a lightweight wallet
- wallet without blockchain, in order to test the daemon
- this lightweight wallet will be later implemented on the card
- use it to define the communication protocol between card and reading device.
3. implement wallet on a simple smart card
- http://www.opensc-project.org/opensc openSC : tools and libraries for smart cards.
- amadousarr.free.fr/crypto/ECDSAJAVACARD.pdf : A Software Implementation of ECDSA on a Java Smart Card
- http://www.acs.com.hk : cards, readers, development kits; no display, pincode needs to be typed on the reading device
4. implement wallet on a smart card with display and pincode
list of vendors:
- http://www.nidsecurity.com/products/solution-enterprise.html (smart cards with LCD displays)
- http://www.avesodisplays.com/ (smard cards with flexible displays)
references
- https://bitcointalk.org/index.php?topic=7539.0 Bitcoin smartcard Point of Sale terminal
- https://bitcointalk.org/index.php?topic=20933.0 Bitcoin and Smart Cards