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Please note that FTE is an invite only, pre-release feature. If you feel the technology described here fits a particular need, please reach out to your Square 9 representative for more details on how you can join the early adopters program.

Square 9 offers a number of traditional OCR options, but also has options that leverage tooling in the areas of AI and ML. While more modern extraction tooling can be very good at decreasing setup time, it’s often not a complete solution. Customer’s may need to blend modern and traditional approaches for extracting data to form a complete / all encompassing data capture platform.

Square 9’s most recent offering in the AI extraction space, dubbed FTE, involves AI assisted extraction models that are largely application/document/form independent. FTE works off of two core constructs: Forms and Tables.

FTE differs from other AI driven extraction offerings from Square 9 like TransformAI. Most notably, it’s not document specific. The tooling can operate on any document type. Like TAI however, successful extraction does have some rules for success. For TAI, those rules revolve around document characteristics that are common among Invoices and Receipts. For FTE, the rules revolve around data points being grouped into either Key / Value pairs and Tables.

Key / Value Pairs

Keys and their associated values are a core construct of extraction with FTE. For the more technical audience, Key / Value pairs are a common idea often used in programing and scripts. In the context of a document however, Key / Value pairs can take on new meaning.

Consider the remittance section of a W.B. Mason invoice:

image-20240327-192730.png

In a traditional extraction model, users are generally less concerned about keys and focus exclusively on values. It would be very simply to create an OCR template that extracted values for Customer Number, Invoice Number, Invoice Date, and Total Due. As your capture needs expand however, this model becomes fragile. Variances in scan resolution might impact positioning, and most certainly, similar documents produced by other vendors will introduce differences in layout. Square 9’s GlobalCapture offers a number of tools to help with such discrepancies in a more traditional manner, whether it be through Marker Zones, pattern matching, etc. FTE takes a different approach.

Rather than using structured or semi-structured templates, FTE leverages the power of AI to make assumptions about the text on a page. Rather than requiring a user to identify via a template that “C8675309” is the customer number, FTE makes the assumptions automatically on behalf of the user. So in the AI assisted world, the OCR result wouldn’t be an arbitrary value “C8675309” that a user has told us should be inferred as Customer Number. Instead, the OCR result would resemble “Key: Customer Number, Value: C8675309”. The same pattern would hold true for all Key / Value pairs identified on the document. So in this case, you would expect to see results like:

"Key":Customer Number","Value":"C8675309"
"Key":"Invoice Number","Value":"I59692155"
"Key":"Invoice Date","Value":"02/11/2024"
"Key":"Terms","Value":"Net 30"
"Key":"Total Due","Value":"71.98"

While the OCR results are extremely good, success does require adherence to a pattern of some kind. In the case of FTE, each value is expected to have a descriptive key in it’s general vicinity. This does not mean keys and values need to be laid out horizontally, nor does it mean grid lines must be present in the document’s layout. It does however mean that for each value one cares to extract, there must in fact be a related key.

And example case where this may present as problematic might be in the upper left corner of the W.B. Mason example above. In this case, both a phone number and a website address are present below the logo and address block.

image-20240327-195425.png

In this example, there are two possible outcomes:

  1. Either the phone number, the website address, or both simply don’t extract.

  2. One or both values extract, but do so with a Key of “Address Service Requested”.

In either case, extracting one or both of these data points is likely better served with an alternate method. Certainly a traditional zone extraction could be perform to collect these data points. Alternately, other use case specific tools like Transform AI (which is tuned specifically for invoices and receipts) looks very specifically for data points that might match phone numbers and website addresses regardless of the presence of a Key.

Despite any limitations presented through the lack of a Key, FTE offer’s a very powerful, very accurate approach to semi-structured and unstructured document extraction that fits well into a large set of extraction use cases.

Tables

In addition to Key / Value extraction, FTE is also very good at identifying and extracting tables. Leveraging the power of AI, FTE can identify formatted tables on a document page. Because it is not bound to a document type, FTE is significantly less rigid about the tables and their associated values when compared to a feature like TAI.

Continuing with the W.B. Mason example, tables are most commonly identified by rows and columns on a page:

image-20240327-203942.png

While the human eye might be able to quickly determine that the table marked (2) is the table of interest for this specific document, the computer can not make such assumptions. In this image snippet, two discrete tables could be identified. Tables are most commonly and most successfully extracted when there are clearly defined rows and columns.

When FTE executes on a document page, it will return the data organized by the table it was identified in. In the case above, we would expect two tables, one with 2 columns and 8 rows (table 1) and one with 2 rows and 6 columns (table 2).

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