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--- power_transfer_architecture_of_the_qi_standard [2025/04/30 15:29] – tm
+++ power_transfer_architecture_of_the_qi_standard [2025/05/01 14:11] (current) – [4.Negotiation phase] tm
@@ Line 1: / Line 1: @@
 =====Power Transfer Architecture of the Qi Standard=====
-====Establishing power transfer====
-The transmitter (Tx) and receiver (Rx) go through an advanced process for power to be transferred. This process comprises **four phases** in the **Baseline Power Profile (BPP)**, namely the selection, ping, identification & configuration, and the power transfer phase. In the **Extended Power Profile (EPP)** and the **Magnetic Power Profile (MPP)** the process is expanded to **seven phases**. In addition to the four phases used in BPP, EPP and MPP introduce the calibration, negotiation, and authentication phases. These phases are discussed and an overview of the two architectures is given in Figure 1 and Figure 2.
+The transmitter (Tx) and receiver (Rx) go through an advanced process for power to be transferred. This process comprises **four phases** in the **baseline power profile (BPP)**, namely the selection, ping, identification & configuration, and power transfer phase. In the **extended power profile (EPP)** and the **magnetic power profile (MPP)** the process is expanded to **seven phases**. In addition to the four phases used in BPP, EPP and MPP introduce the calibration, negotiation, and authentication phases. These protocol phases are discussed in the subsequent chapters. An overview of the two system architectures is presented in Figure 1 and Figure 2.
-**1.	Selection phase**
+====1.	Selection phase====
-The Tx sends out an analog signal to detect placed objects on the base station. This method is based on the shift of the Tx’s resonance frequency. If a Qi-compatible Rx is present, it interacts with the transmitter’s coil which leads to inductive coupling via mutual inductance. This inductive coupling alters the resonance frequency of the transmitter and changes the overall impedance of the system. The transmitter detects this frequency shift, indicating the presence of a potential Qi device. This detection phase does not involve waking up the power receiver. There is no communication between Tx and Rx (The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 124–125).
+In the selection phase, the transmitter (Tx) monitors the characteristics of its resonant circuit to detect the presence of a potential receiver (Rx). This can also be an unwanted foreign object. When a Qi-compatible device is brought near, its coil interacts with the Tx coil through mutual inductance. This coupling alters the Tx's resonance frequency and impedance. By observing these changes, the Tx infers the presence of an object. No data communication occurs at this stage, and the Rx remains inactive (The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 124–125).
-**2.	Ping phase**
+====2.	Ping phase====
-During this phase, the TX emits a low-power signal, typically lasting 40 ms. When a digital ping is executed the Tx listens for a response. When an Rx responds, it sends out a Signal Strength Packet (SSP) or a End Power Transfer Packet (EPTP). If the Rx responds with a SSP, the ping is extended and the system moves into the identification and configuration phase. If the Tx does not receive a response back or an EPTP, the system reverts to the selection phase. (An0578en, 2022, p. 3; The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 46, 51, 73)
+During the ping phase, the Tx emits a low-power signal to detect whether a Qi-compatible Rx is present and responsive. This signal typically lasts 40 milliseconds. When a digital ping is executed the Tx awaits a response. If a Rx is present, the returned power signal is modulated by using **[[bidirectional in-band communication in the Qi standard|amplitude shift keying (ASK)]]**. The response itself takes the form of a Signal Strength Packet (SSP) or an End Power Transfer Packet (EPTP). A valid SSP means that Rx is ready for further communication. Therefore, the Tx extends the ping and transitions into the identification and configuration phase. Conversely, if the Rx sends an EPTP or if no response is received, the system reverts to the selection phase (Holtek, 2022, p. 3; The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 46, 51, 73).
-**3.	Identification and configuration phase**
+====3.	Identification and configuration phase====
-This protocol extends the Digital Ping in order to enable the power receiver to communicate the relevant information. This information is provided as a packet and consists of four parts, namely a preamble, a header, a message and a checksum.
+After a transition to the identification and configuration phase, the Rx begins actively communicating relevant information to the Tx, via ASK. The transmitted data is structured in a packet consisting of four components: a preamble, a header, a message, and a checksum. The Tx, in turn, communicates with the Rx using **[[Bidirectional in-band communication in the Qi standard|frequency shift keying (FSK) modulation]]**.
-All transmitters start in Baseline Power Profile (BPP) and can enter into Extended Power Profile (EPP) or Magnetic Power Profile (MPP) if the Rx supports this version. The check if the power receiver supports the newer profiles is found within the header-part of the packet. Specifically, it can be found in the Extended Identification Packet (EIP).The negotiation phase, calibration phase and authentication phase are only for these advanced power profiles. If the Rx only supports BPP, then the power transfer phase will be entered (The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 88–91).
-**4.	Negotiation phase**
+By default, all transmitters operate in the Baseline Power Profile (BPP). It supports wireless charging up to 5W. The Rx indicates whether it supports a more advanced profile, such as the EPP or newer Qi2-based profiles like the MPP, which support up to 15 W. This information is incorporated in the **extended identification packet (EIP)**, specifically within the **header section** of the packet. If the Rx does not support any advanced power profiles beyond BPP, the protocol immediately transitions into the power transfer phase (7. Power transfer phase). A schematic of this communication architecture is found in Figure 1.
+However, if the Rx indicates support for EPP or MPP than the system proceeds to additional protocol stages such as the negotiation, calibration and authentication phase. In these phases voltage, current and control parameters are negotiated. These steps prepare the system for power levels above 5 W (The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 88–91).
+====4.	Negotiation phase====
 This phase can only be accessed through EPP or MPP capable devices with **[[Foreign object detection in the Qi standard|foreign object detection (FOD)]]**. In this phase the Tx and Rx review their power transfer contract. The purpose of the negotiation phase is to fine-tune this contract. The Rx sends a negotiation request to the Tx to which it replies with a message of granting, denying or not recognising the request. Both the sender and the receiver keep a copy of the current contract. This temporary copy is used to store updated parameters until the negotiation phase is successfully completed.
 As part of this phase, the Rx also sends the reference **[[Foreign object detection in the Qi standard|quality factor (Q-factor)]]** value to the Tx. This value reflects the Q-factor measured under ideal conditions without any foreign objects. The Tx uses this value to determine a threshold for FOD by comparing it with the Q-factor measured on its own primary coil. If the measured Q-factor falls below this threshold, the Tx may terminate the power transfer. These Q-factor evaluations and threshold settings are performed during the negotiation phase to ensure safe and efficient operation.
 With the MPP this process is simplified. The magnetic attachment within the new MPP mode tightly secures transmitter and receiver coils in optimal positions. Therefore, the coupling factor always hovers around a value of 1. This makes the negotiation and FOD procedures faster and more predictable than in EPP (The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 48, 57, 76).
-**5.	Calibration phase**
+====5.	Calibration phase====
 In the calibration phase the TX and Rx can update their power transfer contract with the measurement data from the previous phase. Ideally, the calibration phase should involve the transmitter and receiver testing different power levels to find the appropriate power transfer. While multiple calibration points could provide a more detailed power loss profile, the Qi specification opts for a two-point method to balance accuracy with complexity and duration:
@@ Line 32: / Line 36: @@
 Additionally, if the transmitter detects instability during the calibration (fluctuating control error values, unexpected variations in received power values, inconsistent system responses) it may reject the calibration data. In such cases, the transmitter will discard the calibration attempt and return to the selection phase. By doing so only stable and reliable data is used (Power Solutions for Wireless Charging, 2018, p. 22; The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, pp. 49, 61, 80).
-**6.	Authentication phase**
+====6.	Authentication phase====
-After successful calibration the transmitter enters the initial power transfer mode where it limits the output to 5 watts (BPP mode). During this phase the receiver has the opportunity to request and initiate an authentication challenge. If the authentication process succeeds, the transmitter is permitted to continue with negotiated power delivery up to the maximum supported level. If the authentication challenge fails or is not initiated the transmitter remains limited to 5 watts for the duration of the charging session (Technologies, n.d., p. 25).
+After successful calibration the transmitter enters the initial power transfer mode where it limits the output to 5 watts (BPP mode). During this phase the receiver has the opportunity to request and initiate an authentication challenge. If the authentication process succeeds, the transmitter is permitted to continue with negotiated power delivery up to the maximum supported level. If the authentication challenge fails or is not initiated, the transmitter remains limited to 5 watts for the duration of the charging session (Technologies, n.d., p. 25).
-**7.	Power transfer phase**
+====7.	Power transfer phase====
 In this phase power is delivered from Tx to Rx but more importantly, there is continuous communication ensuring dynamic power control. Also FOD and temperature monitoring are features that need continuous communication. The power transfer phase is the final phase to commence charging the Qi device. There are multiple ways to exit this phase:
@@ Line 43: / Line 47: @@
   * **Safety stop**: The exit can also be triggered by various, previously discussed, safety features: overheating protection, FOD or aborted communication between Tx and Rx.
-The BPP control architecture of the Qi standard is shown in Figure 1. Figure 2 presents the EPP control architecture. This architecture also applies to MPP, as the structure remains the same (An0578en, 2022, p. 4; Evolution of Qi Wireless Charging Standard & What’s New With Qi2, n.d.; The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, p. 48; Technologies, n.d., p. 24).
+The BPP control architecture of the Qi standard is shown in Figure 1. Figure 2 presents the EPP control architecture. This architecture also applies to MPP, as the structure remains the same (GRL, n.d.; Holtek, 2022, p. 4; Technologies, 2023, p. 24; The Qi Wireless Power Transfer System Class 0 Specification 1 and 2: Interface Definitions, 2017, p. 48).
-{{:bpp_architecture_of_communication.png?600|}}
+| {{:bpp_architecture_of_communication.png?600|}}|
-Figure 1 BPP architecture of communication
+| Figure 1 BPP architecture of communication (Holtek, 2022, p. 4) |
-{{:epp_architecture_of_communication.png?600|}}
+| {{:epp_architecture_of_communication.png?800|}} |
-Figure 2 EPP architecture of communication
+| Figure 2 EPP architecture of communication (Technologies, 2023, p. 24) |
@@ Line 53: / Line 58: @@
 <color #808080>**References**</color>
-  * <color #808080>An0578en, N. : (2022). BP66FW1242 Qi Wireless Charger Receiver Application.</color>
+  * <color #808080>Holtek. (2022). BP66FW1242 Qi Wireless Charger Receiver Application. https://www.holtek.com/webapi/116745/an0578env110.pdf</color>
-  * <color #808080>Evolution of Qi Wireless Charging Standard & What’s New With Qi2. (n.d.). Https://Www.Graniteriverlabs.Com/En-Us/Technical-Blog/Qi2-Wireless-Charging-Standards-Evolution?Utm_source=chatgpt.Com.</color>
+  * <color #808080>GRL. (n.d.). Evolution of Qi Wireless Charging Standard & What’s New With Qi2. Https://Www.Graniteriverlabs.Com/En-Us/Technical-Blog/Qi2-Wireless-Charging-Standards-Evolution?</color>
-  * <color #808080>Power solutions for Wireless Charging. (2018).</color>
+  * <color #808080>MPS. (2018). Power solutions for Wireless Charging. https://www.big-bit.com/meeting/2018znkc/images/hhbd/MPS_02.pdf</color>
   * <color #808080>Technologies, I. A. (n.d.). WLC1515, Wireless charging IC (WLC) 15-W transmitter for automotive applications. www.infineon.com</color>
   * <color #808080>The Qi Wireless Power Transfer System Power Class 0 Specification Parts 1 and 2: Interface Definitions. (2017).</color>