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Electrical and electronics engineering

Electrical and electronics engineering

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Electrical engineering Paid promotion @Engineeringupdatess @electricalandelectronics09

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📈 Telegram 频道 Electrical and electronics engineering 的分析概览

频道 Electrical and electronics engineering (@electricalandelectronics09) 英语 语言赛道中的 是活跃参与者。目前社区聚集了 20 061 名订阅者,在 技术与应用 类别中位列第 6 649,并在 印度 地区排名第 21 187

📊 受众指标与增长动态

невідомо 创建以来,项目保持高速增长,吸引了 20 061 名订阅者。

根据 01 七月, 2026 的最新数据,频道保持稳定运转。过去 30 天订阅人数变化为 165,过去 24 小时变化为 -3,整体触达仍然可观。

  • 认证状态: 未认证
  • 互动率 (ER): 平均受众互动率为 35.42%。内容发布后 24 小时内通常能获得 5.43% 的反应,占订阅者总量。
  • 帖子覆盖: 每篇帖子平均可获得 0 次浏览,首日通常累积 1 090 次浏览。
  • 互动与反馈: 受众积极参与,单帖平均反应数为 0
  • 主题关注点: 内容集中在 current, transistor, circuit, mosfet, collector 等核心主题上。

📝 描述与内容策略

作者将该频道定位为表达主观观点的平台:
Electrical engineering Paid promotion @Engineeringupdatess @electricalandelectronics09

凭借高频更新(最新数据采集于 02 七月, 2026),频道始终保持新鲜度与高覆盖。分析显示受众积极互动,使其成为 技术与应用 类别中的关键影响点。

20 061
订阅者
-324 小时
+177
+16530
帖子存档
Common Electrical Engineering Formulas: 1. Ohm's Law: V = I * R - V: Voltage (in volts) - I: Current (in amperes) - R: Resistance (in ohms) 2. Power in a DC Circuit: P = V * I - P: Power (in watts) - V: Voltage (in volts) - I: Current (in amperes) 3. Power in an AC Circuit: P = V * I * cos(θ) - P: Power (in watts) - V: Voltage (in volts) - I: Current (in amperes) - θ: Phase angle between voltage and current 4. Capacitance: C = Q / V - C: Capacitance (in farads) - Q: Electric charge (in coulombs) - V: Voltage (in volts) 5. Inductance: L = Φ / I - L: Inductance (in henries) - Φ: Magnetic flux (in webers) - I: Current (in amperes) 6. Impedance of a Resistor: Z = R - Z: Impedance (in ohms) - R: Resistance (in ohms) 7. Impedance of a Capacitor: Z = 1 / (jωC) - Z: Impedance (in ohms) - j: Imaginary unit (√-1) - ω: Angular frequency (in radians per second) - C: Capacitance (in farads) 8. Impedance of an Inductor: Z = jωL - Z: Impedance (in ohms) - j: Imaginary unit (√-1) - ω: Angular frequency (in radians per second) - L: Inductance (in henries) 9. Kirchhoff's Voltage Law (KVL): Σ(Voltage drops) = Σ(Voltage sources) - The sum of voltage drops across components in a closed loop is equal to the sum of the voltage sources in that loop. 10. Kirchhoff's Current Law (KCL): Σ(Currents entering a node) = Σ(Currents leaving a node) - The sum of currents entering a node is equal to the sum of currents leaving that node.

Electrical transmission 👍👍😍
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Electrical transmission 👍👍😍

Thanks to all subscribers 😍😍👍👍👍
Thanks to all subscribers 😍😍👍👍👍

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