Today, fragments of DGNOG survive in obscure mesh routing layers and a single underwater research station in the Pacific. Every few months, a grad student rediscovers the draft RFC on a forgotten IETF archive, posts a confused tweet, and moves on.
Because networks are built by humans, and humans fear silence. Operators rely on screams. They want SNMP traps, log spikes, red alerts. A node that quietly steps back looks broken, not wise. During the 2021 trials at a midwestern ISP, DGNOG prevented three cascading failures. But it also confused every monitoring dashboard. The NOC team saw green lights where they expected red, shrugged, and disabled the feature. Today, fragments of DGNOG survive in obscure mesh
Most protocols scream until failure. They retransmit, they escalate, they flood. DGNOG did the opposite. Operators rely on screams
Today, fragments of DGNOG survive in obscure mesh routing layers and a single underwater research station in the Pacific. Every few months, a grad student rediscovers the draft RFC on a forgotten IETF archive, posts a confused tweet, and moves on.
Because networks are built by humans, and humans fear silence. Operators rely on screams. They want SNMP traps, log spikes, red alerts. A node that quietly steps back looks broken, not wise. During the 2021 trials at a midwestern ISP, DGNOG prevented three cascading failures. But it also confused every monitoring dashboard. The NOC team saw green lights where they expected red, shrugged, and disabled the feature.
Most protocols scream until failure. They retransmit, they escalate, they flood. DGNOG did the opposite.