Introduction

OverviewData TypesFile TypesHTTP APIOntologyDefs

Overview

Project Haystack is an open source suite of technologies for modeling IoT data. The stack of technologies includes:

  • Data Types: a fixed set of data types for modeling information
  • File Types: a set of text formats to encode and exchange those data types
  • HTTP API: a protocol to exchange data over HTTP using those file types
  • Ontology: a standard way to model common concepts such as buildings, spaces, equipment, and sensors
  • Defs: a standard way to define and extend the ontology

Individual aspects of the technology stack can be used on their own. For example you can use the Haystack data types as an "enhanced JSON". Or you could use just the terms in the ontology without the Haystack data types.

Data Types

Haystack defines a fixed set of general purpose data types we call kinds to facilitate the interoperable exchange of data. These data types include the basics like strings and numbers, as well as common types for times and dates. Three collection types are defined: lists, dicts (hashmaps), and grids (tables).

You can think of Haystack as an extended version of JSON. Haystack supports the JSON data types directly: boolean, strings, numbers, lists, and objects (dicts). But Haystack adds first class types for time, URIs, references, and units of measurement.

The primary collection type is the dict (short for dictionary) which is a set of name/value pairs we call tags. Dict is the Haystack term for an associative array, hashmap, or JSON object. Haystack models entities like buildings and sensors using dicts. The tags of the dict inform what type of entity is modeled and facts about that entity.

Haystack includes a special data type we call marker. Markers are tag names without a value. Instead it is the presence of the marker name that is semantically meaningful. Markers are used for typing dicts. For example if a dict models a building then we use the marker tag site; or if a dict models an electric meter than we use the combination of markers tags elec-meter.

These data types are discussed in detail in the Kinds chapter.

File Types

A standard suite of text formats is defined to exchange the Haystack data types. These formats are self describing to ensure that all data types will round-trip through the encoding/decoding process without loss of typing information.

The following file types are standardized:

  • Zinc: a strongly typed CSV tabular data format
  • Json: Haystack mapping to JSON data types
  • Trio: a YAML like format used for hand written data
  • CSV: one-way mapping to comma separated values (typing is lost)
  • RDF: two RDF export formats are defined - Turtle and JSON-LD

The file types are discussed further in the Filetypes chapter.

HTTP API

A simple HTTP protocol is specified by Haystack to facilitate exchanging data between servers and devices. The protocol is based on a set of ops (short for operations) that provide a RPC mechanism to send a request and receive a response as grids encoded in one of the supported file types. Included in the specification is a pluggable SCRAM based authentication protocol.

Some of the standard ops used for common IoT data exchanges:

  • read: query entity data about buildings, rooms, or sensors
  • hisRead: read historized time-series point data
  • hisWrite: push historized time-series to a remote system
  • watchSub: subscribe to real-time sensor data

Ontology

Project Haystack is focused on the semantic data model for the IoT and the built environment. We specify an ontology to standardize modeling of common concepts in this domain including:

  • site: a single building or location of equipment/sensors
  • space: a floor, room, HVAC zone, lighting zone, etc
  • equip: a physical asset such as a meter, air handler, boiler, etc
  • point: a sensor, setpoint, or actuator
  • device: microprocessor based hardware such as controllers, networking gear, etc
  • weather: weather observations for temperature, humidity, precipitation, etc

Each of these top-level concepts includes a taxonomy tree for more specific types. For example, the term space is the root of the taxonomy that includes floor, room, and zones. All the concepts modeled in our ontology are formalized into a vocabulary of terms that map to the tags used in dicts.

Let's illustrate with a simple example. This a dict that models a building:

id: @whitehouse
dis: "White House"
site
area: 55000ft²
geoAddr: "1600 Pennsylvania Avenue NW,  Washington, DC"
tz: "New_York"
weatherStationRef: @weather.washington

Each line represents a tag (name/value) pair. Each tags tells us something about this entity:

  • id: primary key for this data item (within its data set)
  • dis: human display name for the data item
  • site: marker tag that tells us this data represents a building
  • area: square footage of the building
  • geoAddr: street address of the building
  • tz: timezone to use for this building
  • weatherStationRef: relationship for which weather station to use for this building

These concepts are explored further in the Ontology chapter and the individual chapters for specific systems.

Defs

Defs (or definitions) are the mechanism by which we formally define our ontology. Defs are used to define the semantics for each tag including:

  • value type (marker, string, number, etc)
  • the supertype (for example a more specific type of space, equip, etc)
  • human description for the tag
  • ontological relationships for how tags relate to one another

By precisely defining every tag, we ensure that there is a common understanding for the semantics of a Haystack data model. In our example above, we know that dict represents a building (the site tag) and that the area tag tells us the square footage of the building.

Defs are themselves just a dict that uses a standard set of meta tags for their definition. This means defs are also normal Haystack data. For example, the def for the floor tag is itself a dict of the following tags:

def: ^floor
is: ^space
wikipedia: `https://en.wikipedia.org/wiki/Storey`
doc: "Storey of a building"

Defs, and the mechanisms used to construct the ontology, are introduced in detail in the Defs chapter.