Asymmetrical communications
Water depth increases downstream due to a combination of factors such as the accumulation of flow from tributaries, reduced friction along the river bed, and the energy gradient of the river. As the river flows downstream, it gains more volume and velocity, resulting in higher water depth.
A stream's velocity typically increases downstream due to the accumulation of water volume and slope gradient. This leads to higher flow rates and faster-moving water.
Average velocity increases downstream because of the overall flow of the river. As the river moves in the downstream direction, the volume of water increases due to tributaries adding water along the way. This increase in water volume results in a higher average velocity as the same amount of water needs to flow through a larger channel.
The value with the higher frequency is the one that occurs more often in a dataset or sample population.
The steeper the slope, the faster the water will flow downhill due to gravity pulling it more strongly. A steeper slope provides a greater force that propels the water downstream at a higher velocity.
In asymmetrical communication, downstream throughput is higher than upstream throughput.
Asymmetric dsl (ADSL) Rate-adaptive DSL (RADSL)
If the fault is a direct short to ground, the fault current can be high enough to trip the upstream protection.
In an Asymmetric Digital Subscriber Line (ADSL), the downstream speed is higher than the upstream speed because the technology is designed to prioritize downloading data, which is typically more demanding for users. ADSL achieves this by allocating more bandwidth to the downstream channel, allowing for faster data transmission from the internet to the user. This asymmetry is beneficial for activities like streaming, browsing, and downloading, which are more common than uploading. Consequently, the configuration optimizes the user experience by catering to typical internet usage patterns.
glaciers move them downhill and scratch the surface of the valley from a river 'v' to a glacial 'u' they also move lots of rocks. rivers move rocks downstream the higher upstream the more rough and sharp edged they are, downstream they are smoother and rounder due to erosion.
Bandwidth refers to the maximum data transfer capacity of a network connection, while throughput is the actual amount of data transmitted over that connection in a given time period. Generally, higher bandwidth can lead to higher throughput, but factors like network congestion, latency, and protocol overhead can affect this relationship. Therefore, while bandwidth sets the potential upper limit for throughput, real-world conditions often result in throughput being lower than the available bandwidth.
(1) the higher the twist, the higher the throughput (2) The higher the twist, the the lower the crosstalk
Response time and throughput in a system are inversely related. As response time decreases, throughput typically increases, and vice versa. This means that as the system processes tasks more quickly (lower response time), it can handle more tasks in a given time period (higher throughput).
It's not based on the location on a map. It is more geographical. The "lower Canada region" is more upriver on the St Lawrence. The higher up the river, the "lower" you are. Upper Canada or "Ontario" is located at the tip of the river. Settlers arrived through the St Lawrence and believed the entrance to the river was lower, and the end of the river was higher. ============================================================ "Upper Canada" and "Lower Canada" were named because of their relative elevations and their relative locations on the St Lawrence watershed. Upper Canada was upstream, and at a higher elevation; Lower Canada was downstream, and at a lower elevation.
Changes both upstream and downstream habitat to both water and land Can displace people - sometimes 100,000s Can impact fish migration patterns Puts canyons under water and sometimes destroys recreation areas Much higher levels of water evaporation
Data is usually higher in wired network then wireless. This is because to is plugged directly in.
Note: "integration" and "merger" are the same Benefits of Vertical integrationVertical integration potentially offers the following advantages:Reduce transportation costs if common ownership results in closer geographic proximity.Improve supply chain coordination.Provide more opportunities to differentiate by means of increased control over inputs.Capture upstream or downstream profit margins.Increase entry barriers to potential competitors, for example, if the firm can gain sole access to a scarce resource.Gain access to downstream distribution channels that otherwise would be inaccessible.Facilitate investment in highly specialized assets in which upstream or downstream players may be reluctant to invest.Lead to expansion of core competencies.Drawbacks of Vertical integrationWhile some of the benefits of vertical integration can be quite attractive to the firm, the drawbacks may negate any potential gains. Vertical integration potentially has the following disadvantages:Capacity balancing issues. For example, the firm may need to build excess upstream capacity to ensure that its downstream operations have sufficient supply under all demand conditions.Potentially higher costs due to low efficiencies resulting from lack of supplier competition.Decreased flexibility due to previous upstream or downstream investments. (Note however, that flexibility to coordinate vertically-related activities may increase.)Decreased ability to increase product variety if significant in-house development is required.Developing new core competencies may compromise existing competencies.Increased bureaucratic costs.