Photo album web application that can be searched using natural language through both text and voice. This application uses Lex, ElasticSearch, and Rekognition to create an intelligent search layer to query your photos for people, objects, actions, landmarks and more.
There are 5 components:
a. Using AWS ElasticSearch service , create a new domain called “photos”.
b. Make note of the Security Group (SG1) you attach to the domain.
c. Deploy the service inside a VPC. This prevents unauthorized internet access to your service.
a. Create a S3 bucket (B2) to store the photos.
b. Create a Lambda function (LF1) called “index-photos”.
i. Launch the Lambda function inside the same VPC as ElasticSearch. This ensures that the function can reach the ElasticSearch instance.<br/>
ii. Make sure the Lambda has the same Security Group (SG1) as ElasticSearch.
c. Set up a PUT event trigger on the photos S3 bucket (B2), such that whenever a photo gets uploaded to the bucket, it triggers the Lambda function (LF1) to index it.
i. To test this functionality, upload a file to the photos S3 bucket (B2) and check the logs of the indexing Lambda function (LF1) to see if it got invoked. If it did, your setup is complete.
* If the Lambda (LF1) did not get invoked, check to see if you set up the correct permissions for S3 to invoke your Lambda function.
d. Implement the indexing Lambda function (LF1):
i. Given a S3 PUT event (E1) detect labels in the image, using Rekognition (“detectLabels” method).
ii. Store a JSON object in an ElasticSearch index (“photos”) that references the S3 object from the PUT event (E1) and an array of string labels, one for each label detected by Rekognition.
Use the following schema for the JSON object:
```
{
“objectKey”: “my-photo.jpg”,
“bucket”: “my-photo-bucket”,
“createdTimestamp”: “2018-11-05T12:40:02”,
“labels”: [
“person”,
“dog”,
“ball”,
“park”
]
}
```
a. Create a Lambda function (LF2) called “search-photos”.
i. Launch the Lambda function inside the same VPC as ElasticSearch. This ensures that the function can reach the ElasticSearch instance.
ii. Make sure the Lambda has the same Security Group (SG1) as ElasticSearch.
b. Create an Amazon Lex bot to handle search queries.
i. Create one intent named “SearchIntent”.
ii. Add training utterances to the intent, such that the bot can pick up both keyword searches (“trees”, “birds”), as well as sentence searches (“show me trees”, “show me photos with trees and birds in them”).
* You should be able to handle at least one or two keywords per query.
c. Implement the Search Lambda function (LF2):
i. Given a search query “q”, disambiguate the query using the Amazon Lex bot.
ii. If the Lex disambiguation request yields any keywords (K1, …, Kn), search the “photos” ElasticSearch index for results, and return them accordingly (as per the API spec).
* You should look for ElasticSearch SDK libraries to perform the search.
iii. Otherwise, return an empty array of results (as per the API spec).
a. Build an API using API Gateway.
i. The Swagger API documentation for the API can be found here:
https://github.com/001000001/ai-photo-search-columbia-f2018/blob/master/swagger.yaml
b. The API should have two methods:
i. PUT /photos
Set up the method as an Amazon S3 Proxy . This will allow API Gateway to forward your PUT request directly to S3.
ii. GET /search?q={query text}
Connect this method to the search Lambda function (LF2).
c. Setup an API key for your two API methods.
d. Deploy the API.
e. Generate a SDK for the API (SDK1).
a. Build a simple frontend application that allows users to:
i. Make search requests to the GET /search endpoint
ii. Display the results (photos) resulting from the query
iii. Upload new photos using the PUT /photos
b. Create a S3 bucket for your frontend (B2).
c. Set up the bucket for static website hosting.
d. Upload the frontend files to the bucket (B2).
e. Integrate the API Gateway-generated SDK (SDK1) into the frontend, to connect your API.