SpeedFromLoadTask

Seed 1

The wind tunnel is a chamber with one controllable fan that pushes air through it. We can control the load of the fan (corresponding to the duty cycle of the pulse-width-modulation signal) and measure its speed (in revolutions per minute). The fan is designed so its steady-state speed scales broadly linearly with the load. Unless completely powered off, the fan never operates below a certain speed, corresponding to a minimum effective load between 0.1 and 0.2. The task is to forecast the speed of the fan.

The load is set to: 0.0 until 05:47:09, 0.1 from 05:47:09 until 05:47:29, 0.0 from 05:47:29 until 05:48:01, 0.2 from 05:48:01 until 05:48:27, 0.1 from 05:48:27 until 05:48:49, 0.0 from 05:48:49 until 05:49:00.

Constraints: The load is between 0 and 1. At full load (=1), the fan turns at a maximum speed of 3000 rpm.

Types of context: ['Covariate information', 'Causal information', 'Intemporal information']

Capabilities: ['Reasoning: Causal', 'Reasoning: Math', 'Instruction Following']

Seed 2

The wind tunnel is a chamber with one controllable fan that pushes air through it. We can control the load of the fan (corresponding to the duty cycle of the pulse-width-modulation signal) and measure its speed (in revolutions per minute). The fan is designed so its steady-state speed scales broadly linearly with the load. Unless completely powered off, the fan never operates below a certain speed, corresponding to a minimum effective load between 0.1 and 0.2. The task is to forecast the speed of the fan.

The load is set to: 0.0 until 05:25:04, 0.1 from 05:25:04 until 05:25:44, 0.2 from 05:25:44 until 05:26:07, 0.1 from 05:26:07 until 05:26:25, 0.2 from 05:26:25 until 05:27:09, 0.5 from 05:27:09 until 05:27:17.

Constraints: The load is between 0 and 1. At full load (=1), the fan turns at a maximum speed of 3000 rpm.

Types of context: ['Covariate information', 'Causal information', 'Intemporal information']

Capabilities: ['Reasoning: Causal', 'Reasoning: Math', 'Instruction Following']

Seed 3

The wind tunnel is a chamber with one controllable fan that pushes air through it. We can control the load of the fan (corresponding to the duty cycle of the pulse-width-modulation signal) and measure its speed (in revolutions per minute). The fan is designed so its steady-state speed scales broadly linearly with the load. Unless completely powered off, the fan never operates below a certain speed, corresponding to a minimum effective load between 0.1 and 0.2. The task is to forecast the speed of the fan.

The load is set to: 0.1 until 05:30:23, 0.0 from 05:30:23 until 05:30:49, 0.1 from 05:30:49 until 05:31:26, 0.0 from 05:31:26 until 05:32:07, 0.5 from 05:32:07 until 05:32:42, 0.1 from 05:32:42 until 05:33:14, 0.5 from 05:33:14 until 05:33:52, 0.1 from 05:33:52 until 05:34:29, 0.2 from 05:34:29 until 05:34:46.

Constraints: The load is between 0 and 1. At full load (=1), the fan turns at a maximum speed of 3000 rpm.

Types of context: ['Covariate information', 'Causal information', 'Intemporal information']

Capabilities: ['Reasoning: Causal', 'Reasoning: Math', 'Instruction Following']

Seed 4

The wind tunnel is a chamber with one controllable fan that pushes air through it. We can control the load of the fan (corresponding to the duty cycle of the pulse-width-modulation signal) and measure its speed (in revolutions per minute). The fan is designed so its steady-state speed scales broadly linearly with the load. Unless completely powered off, the fan never operates below a certain speed, corresponding to a minimum effective load between 0.1 and 0.2. The task is to forecast the speed of the fan.

The load is set to: 0.2 until 05:36:27, 0.0 from 05:36:27 until 05:37:07, 0.1 from 05:37:07 until 05:37:22.

Constraints: The load is between 0 and 1. At full load (=1), the fan turns at a maximum speed of 3000 rpm.

Types of context: ['Covariate information', 'Causal information', 'Intemporal information']

Capabilities: ['Reasoning: Causal', 'Reasoning: Math', 'Instruction Following']

Seed 5

The wind tunnel is a chamber with one controllable fan that pushes air through it. We can control the load of the fan (corresponding to the duty cycle of the pulse-width-modulation signal) and measure its speed (in revolutions per minute). The fan is designed so its steady-state speed scales broadly linearly with the load. Unless completely powered off, the fan never operates below a certain speed, corresponding to a minimum effective load between 0.1 and 0.2. The task is to forecast the speed of the fan.

The load is set to: 0.0 until 05:41:49, 0.2 from 05:41:49 until 05:42:17, 0.0 from 05:42:17 until 05:42:35, 0.5 from 05:42:35 until 05:43:00, 0.1 from 05:43:00 until 05:43:30.

Constraints: The load is between 0 and 1. At full load (=1), the fan turns at a maximum speed of 3000 rpm.

Types of context: ['Covariate information', 'Causal information', 'Intemporal information']

Capabilities: ['Reasoning: Causal', 'Reasoning: Math', 'Instruction Following']