Jonathan M Hromi

8584219, Nov 12, 2013

Nov 7, 2012

13/670698

Robert C. Toole - Hingham MA, US
Jonathan Hromi - Watertown MA, US
John McDonough - Nahant MA, US
Hadley Rupert Stern - West Newton MA, US
Seth Warren Brooks - South Easton MA, US

FMR LLC - Boston MA

H04L 29/06

726 7, 726 25

A computer-implemented method comprising: receiving, from a device used by a user, a request to access a resource hosted by a computer system; identifying, by the computer system, a level of risk associated with the user requesting access to the resource; adjusting, by the computer system an authentication standard for access to the resource, adjusting based on the identified level of risk; determining values for authentication factors used in authenticating the user's access to the resource; applying weights to the values for the authentication factors; and determining, based on a comparison of the weighted values to the adjusted authentication standard, whether the user is authorized to access the resource.

20230053709, Feb 23, 2023

Oct 24, 2022

17/972559

- Boston MA, US
Thomas Stephen McGuire - Gaway, IE
Amanda Chiu - San Francisco CA, US
Jonathan Hromi - Watertown MA, US
Raghav Chawla - Cambridge MA, US

G06Q 20/36
G06Q 20/06
G06Q 20/38
G06Q 20/40
H04L 9/14
H04L 9/32

The Computationally Efficient Transfer Processing, Auditing, and Search Apparatuses, Methods and Systems (“SOCOACT”) transforms smart contract request, crypto currency deposit request, crypto collateral deposit request, crypto currency transfer request, crypto collateral transfer request inputs via SOCOACT components into transaction confirmation outputs. Also, SOCOACT transforms transaction record inputs via SOCOACT components into matrix and list tuple outputs for computationally efficient auditing. A blockchain transaction data auditing apparatus comprises a blockchain recordation component, a matrix Conversion component, and a bloom filter component. The blockchain recordation component receives a plurality of transaction records for each of a plurality of transactions, each transaction record comprising a source address, a destination address, a transaction amount and a timestamp of a transaction; the source address comprising a source wallet address corresponding to a source digital wallet, and the destination address comprising a destination wallet address corresponding to a destination virtual currency wallet; verifies that the transaction amount is available in the source virtual currency wallet; and when the transaction amount is available, cryptographically records the transaction in a blockchain comprising a plurality of hashes of transaction records. The Bloom Filter component receives the source address and the destination address, hashes the source address using a Bloom Filter to generate a source wallet address, and hashes the destination address using the Bloom Filter to generate a destination wallet address. The Matrix Conversion component adds the source wallet address as a first row and a column entry to a stored distance matrix representing the plurality of transactions, adds the destination wallet address as a second row and column entry to the stored distance matrix representing the plurality of transactions, adds the transaction amount and the timestamp as an entry to the row corresponding to the source wallet address and the column corresponding to the destination wallet address; and generate a list representation of the matrix, where each entry in the list comprises a tuple having the source wallet address, the destination wallet address, the transaction amount and the timestamp.

20170228731, Aug 10, 2017

Feb 9, 2016

15/019926

- Boston MA, US
Thomas McGuire - Galway, IE
Amanda Chiu - San Francisco CA, US
Jonathan Hromi - Watertown MA, US
Raghav Chawla - Cambridge MA, US

G06Q 20/40
G06Q 20/38

The Computationally Efficient Transfer Processing and Auditing Apparatuses, Methods and Systems (“CETPA”) transforms transaction record inputs via CETPA components into matrix and list tuple outputs for computationally efficient auditing. A blockchain transaction data auditing apparatus comprises a blockchain recordation component, a matrix Conversion component, and a bloom filter component. The blockchain recordation component receives a plurality of transaction records for each of a plurality of transactions, each transaction record comprising a source address, a destination address, a transaction amount and a timestamp of a transaction; the source address comprising a source wallet address corresponding to a source digital wallet, and the destination address comprising a destination wallet address corresponding to a destination virtual currency wallet; verifies that the transaction amount is available in the source virtual currency wallet; and when the transaction amount is available, cryptographically records the transaction in a blockchain comprising a plurality of hashes of transaction records. The Bloom Filter component receives the source address and the destination address, hashes the source address using a Bloom Filter to generate a source wallet address, and hashes the destination address using the Bloom Filter to generate a destination wallet address. The Matrix Conversion component adds the source wallet address as a first row and a column entry to a stored distance matrix representing the plurality of transactions, adds the destination wallet address as a second row and column entry to the stored distance matrix representing the plurality of transactions, adds the transaction amount and the timestamp as an entry to the row corresponding to the source wallet address and the column corresponding to the destination wallet address; and generate a list representation of the matrix, where each entry in the list comprises a tuple having the source wallet address, the destination wallet address, the transaction amount and the timestamp.

20170221052, Aug 3, 2017

Apr 12, 2017

15/486243

- Boston MA, US
Thomas Stephen McGuire - Galway, IE
Amanda Chiu - San Francisco CA, US
Jonathan Hromi - Watertown MA, US
Raghav Chawla - Cambridge MA, US

G06Q 20/36
G06Q 20/38
H04L 9/32
H04L 9/06
H04L 9/14
H04L 9/30
G06Q 20/06
G06Q 20/40

The Computationally Efficient Transfer Processing, Auditing, and Search Apparatuses, Methods and Systems (“SOCOACT”) transforms smart contract request, crypto currency deposit request, crypto collateral deposit request, crypto currency transfer request, crypto collateral transfer request inputs via SOCOACT components into transaction confirmation outputs. Also, SOCOACT transforms transaction record inputs via SOCOACT components into matrix and list tuple outputs for computationally efficient auditing. A blockchain transaction data auditing apparatus comprises a blockchain recordation component, a matrix Conversion component, and a bloom filter component. The blockchain recordation component receives a plurality of transaction records for each of a plurality of transactions, each transaction record comprising a source address, a destination address, a transaction amount and a timestamp of a transaction; the source address comprising a source wallet address corresponding to a source digital wallet, and the destination address comprising a destination wallet address corresponding to a destination virtual currency wallet; verifies that the transaction amount is available in the source virtual currency wallet; and when the transaction amount is available, cryptographically records the transaction in a blockchain comprising a plurality of hashes of transaction records. The Bloom Filter component receives the source address and the destination address, hashes the source address using a Bloom Filter to generate a source wallet address, and hashes the destination address using the Bloom Filter to generate a destination wallet address. The Matrix Conversion component adds the source wallet address as a first row and a column entry to a stored distance matrix representing the plurality of transactions, adds the destination wallet address as a second row and column entry to the stored distance matrix representing the plurality of transactions, adds the transaction amount and the timestamp as an entry to the row corresponding to the source wallet address and the column corresponding to the destination wallet address; and generate a list representation of the matrix, where each entry in the list comprises a tuple having the source wallet address, the destination wallet address, the transaction amount and the timestamp.

20170109735, Apr 20, 2017

Jul 14, 2016

15/210781

- Boston MA, US
Thomas McGuire - Galway, IE
Amanda Chiu - San Francisco CA, US
Jonathan Hromi - Watertown MA, US
Raghav Chawla - Cambridge MA, US

G06Q 20/36
H04L 9/32
G06Q 20/40

The Computationally Efficient Transfer Processing, Auditing, and Search Apparatuses, Methods and Systems (“SOCOACT”) transforms smart contract request, crypto currency deposit request, crypto collateral deposit request, crypto currency transfer request, crypto collateral transfer request inputs via SOCOACT components into transaction confirmation outputs. Also, SOCOACT transforms transaction record inputs via SOCOACT components into matrix and list tuple outputs for computationally efficient auditing. A blockchain transaction data auditing apparatus comprises a blockchain recordation component, a matrix Conversion component, and a bloom filter component. The blockchain recordation component receives a plurality of transaction records for each of a plurality of transactions, each transaction record comprising a source address, a destination address, a transaction amount and a timestamp of a transaction; the source address comprising a source wallet address corresponding to a source digital wallet, and the destination address comprising a destination wallet address corresponding to a destination virtual currency wallet; verifies that the transaction amount is available in the source virtual currency wallet; and when the transaction amount is available, cryptographically records the transaction in a blockchain comprising a plurality of hashes of transaction records. The Bloom Filter component receives the source address and the destination address, hashes the source address using a Bloom Filter to generate a source wallet address, and hashes the destination address using the Bloom Filter to generate a destination wallet address. The Matrix Conversion component adds the source wallet address as a first row and a column entry to a stored distance matrix representing the plurality of transactions, adds the destination wallet address as a second row and column entry to the stored distance matrix representing the plurality of transactions, adds the transaction amount and the timestamp as an entry to the row corresponding to the source wallet address and the column corresponding to the destination wallet address; and generate a list representation of the matrix, where each entry in the list comprises a tuple having the source wallet address, the destination wallet address, the transaction amount and the timestamp.

20140379544, Dec 25, 2014

Jun 21, 2013

13/923919

- Boston MA, US
Robert C. Toole - Hingham MA, US
John McDonough - Nahant MA, US
Jonathan Hromi - Watertown MA, US
Seth Warren Brooks - South Easton MA, US

G06Q 40/04

705 37

A computer-implemented method is provided for opening an expedited account for a user. The method includes receiving a request from the user to make a trade associated with at least one financial instrument, in the absence of an account being opened for the user. The method includes determining a plurality of factors in response to the request, the plurality of factors including 1) a credit worthiness score of the user; 2) a source of capital identified by the user to cover the trade; and 3) a type of the at least one financial instrument associated with the trade. The method also includes opening the expedited account for the user with limited trading privileges, in which an amount of fund for trading is advanced to the user based on the plurality of factors. The method further includes allowing the user to make a trade up to the amount of fund advanced.

20140331293, Nov 6, 2014

Jul 21, 2014

14/336620

- Boston MA, US
Jonathan Hromi - Watertown MA, US
John McDonough - Nahant MA, US
Hadley Rupert Stern - West Newton MA, US
Seth Warren Brooks - South Easton MA, US

G06F 21/60

726 5

A computer-implemented method comprising: receiving, from a device used by a user, a request to access a resource hosted by a computer system; identifying, by the computer system, a level of risk associated with the user requesting access to the resource; adjusting, by the computer system an authentication standard for access to the resource, adjusting based on the identified level of risk; determining values for authentication factors used in authenticating the user's access to the resource; applying weights to the values for the authentication factors; and determining, based on a comparison of the weighted values to the adjusted authentication standard, whether the user is authorized to access the resource.

20140130127, May 8, 2014

Oct 10, 2013

14/050718

- Boston MA, US
Jonathan Hromi - Watertown MA, US
John McDonough - Nahant MA, US
Hadley Rupert Stern - West Newton MA, US
Seth Warren Brooks - South Easton MA, US

FMR LLC - Boston MA

G06F 21/31

726 3

A computer-implemented method comprising: receiving, from a device used by a user, a request to access a resource hosted by a computer system; identifying, by the computer system, a level of risk associated with the user requesting access to the resource; adjusting, by the computer system an authentication standard for access to the resource, adjusting based on the identified level of risk; determining values for authentication factors used in authenticating the user's access to the resource; applying weights to the values for the authentication factors; and determining, based on a comparison of the weighted values to the adjusted authentication standard, whether the user is authorized to access the resource.