Ipvr-264 ❲AUTHENTIC❳
where σ is the ReLU function. Offline training minimizes mean‑square error (MSE) over a
for buck, and analogous for boost. A floor of 0.5 MHz prevents sub‑harmonic oscillations; a ceiling of 5 MHz caps switching losses. The perceptron computes:
| Unit | Function | Key Parameters | |------|----------|----------------| | PLE | Predict next‑cycle load current based on recent activity (last 8 samples) using a two‑layer perceptron (8 × 4 × 1) with ReLU activation. | 32 bytes SRAM, 0.8 µW power | | DFS | Adjust the switching frequency f_sw between 0.5 MHz and 5 MHz to maintain a target inductor current ripple (I_ripple = 15 % of I_load). | Frequency step 0.5 MHz | | MDL | Decide buck or boost mode, and set the PWM duty ratio D = Vout/Vin (buck) or D = Vin/(Vout + V_f) (boost). | Hysteresis 50 mV | IPVR-264
Recent research has explored adaptive regulators that modulate architecture or control parameters in response to workload, yet most solutions rely on pre‑programmed heuristics, limiting their ability to cope with highly stochastic traffic patterns typical of edge‑node radios (e.g., BLE advertising, LoRaWAN Class A uplinks) [4]. Moreover, the lack of a unified approach that simultaneously addresses mode transition losses , dynamic load prediction , and switching‑frequency optimization leaves a substantial gap in achieving true ultra‑low‑power operation.
[ f_sw = \fracV_in - V_outL_1 \cdot I_ripple ] where σ is the ReLU function
– A zero‑voltage‑transition (ZVT) driver ensures that the MOSFETs turn on/off when their drain‑source voltage is near zero, suppressing shoot‑through. A soft‑switch capacitor C_ZVT stores the gate charge, enabling sub‑nanosecond turn‑on times. 3.2 Adaptive Controller (ACC) The ACC is implemented in a 6‑bit micro‑coded finite‑state machine (FSM) operating at 500 kHz. Its three functional units are:
[ \hatI load[k+1] = \sigma!\Big(\sum i=0^7 w_i \cdot I_load[k-i] + b\Big) ] The perceptron computes: | Unit | Function |
Keywords : Power management IC, buck‑boost converter, machine‑learning control, IoT, ultra‑low‑power, dynamic frequency scaling. The IoT ecosystem now exceeds 30 billion connected devices, many of which are constrained to sub‑milliwatt power budgets and operate on small coin‑cell or thin‑film batteries [1]. Conventional power‑regulation techniques—linear low‑dropout regulators (LDOs) for low‑noise needs and buck‑boost converters for wide input‑output ranges—each excel in a narrow operating regime but suffer from either high quiescent current (LDO) or sub‑optimal efficiency during low‑load periods (buck‑boost) [2,3].