TW201602774A - Power control method, mobile device, and power control system utilizing the same - Google Patents
Power control method, mobile device, and power control system utilizing the same Download PDFInfo
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- TW201602774A TW201602774A TW104120105A TW104120105A TW201602774A TW 201602774 A TW201602774 A TW 201602774A TW 104120105 A TW104120105 A TW 104120105A TW 104120105 A TW104120105 A TW 104120105A TW 201602774 A TW201602774 A TW 201602774A
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/02—Power saving arrangements
- H04W52/0209—Power saving arrangements in terminal devices
- H04W52/0225—Power saving arrangements in terminal devices using monitoring of external events, e.g. the presence of a signal
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W52/00—Power management, e.g. TPC [Transmission Power Control], power saving or power classes
- H04W52/02—Power saving arrangements
- H04W52/0209—Power saving arrangements in terminal devices
- H04W52/0225—Power saving arrangements in terminal devices using monitoring of external events, e.g. the presence of a signal
- H04W52/0235—Power saving arrangements in terminal devices using monitoring of external events, e.g. the presence of a signal where the received signal is a power saving command
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02D—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN INFORMATION AND COMMUNICATION TECHNOLOGIES [ICT], I.E. INFORMATION AND COMMUNICATION TECHNOLOGIES AIMING AT THE REDUCTION OF THEIR OWN ENERGY USE
- Y02D30/00—Reducing energy consumption in communication networks
- Y02D30/70—Reducing energy consumption in communication networks in wireless communication networks
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Abstract
Description
本發明係有關於功率控制,尤指功率控制方法、以及使用該功率控制方法之行動裝置和功率控制系統。 The present invention relates to power control, and more particularly to a power control method, and a mobile device and power control system using the power control method.
近年來,使用者已逐漸改變使用行動通訊裝置,例如智能手機與平板電腦的習慣,包含日常生活紀錄與分享、公司或業務上的聯繫、教育發展所需以及休閒娛樂功能。藉此,電信商為了滿足使用者需求,紛紛提升無線網路頻寬。 In recent years, users have gradually changed the habit of using mobile communication devices, such as smart phones and tablets, including daily life records and sharing, company or business contacts, educational development needs, and recreational functions. In this way, telecom operators have increased the bandwidth of wireless networks in order to meet the needs of users.
功率放大器(Power Amplifier-PA)係於行動通訊裝置之射頻發射電路中一個重要的元件,其主要的功能在於將訊號放大推出,通常都會被設計在天線的前端,也是整個射頻前端電路中最耗功耗的元件。而越來越大的無線頻寬需求,對於射頻前端電路在功率消耗問題便顯得重要。為了提升功率放大器的附加功率效率(Power Added Efficiency,以下稱為PAE),現今功率放大器設計便由數個增益模式所組成的放大器。各增益模式之間部分重疊,配合增益模式之間切換點(PA切換點,以下稱為PASP)設計,功率放大器即可提供連續且 穩定的線性輸出功率。由於功率放大器具有數個增益模式,增益模式間相互重疊的範圍提供設計射頻前端電路的工程師有足夠的空間來設計或決定功率放大器增益切換範圍的位置,而功率放大器增益切換範圍的決定將間接地影響行動通訊裝置的電池壽命。 Power Amplifier (PA) is an important component in the RF transmitting circuit of mobile communication devices. Its main function is to amplify the signal, which is usually designed at the front end of the antenna, and is also the most expensive in the entire RF front-end circuit. Power components. And the increasing demand for wireless bandwidth is important for the power consumption problem of the RF front-end circuit. In order to increase the power efficiency of the power amplifier (hereinafter referred to as PAE), today's power amplifier design is composed of several gain modes. Partially overlapping between the gain modes, in conjunction with the switching point between the gain modes (PA switching point, hereinafter referred to as PASP), the power amplifier can provide continuous Stable linear output power. Since the power amplifier has several gain modes, the range in which the gain modes overlap each other provides that the engineer designing the RF front-end circuit has enough room to design or determine the position of the power amplifier gain switching range, and the decision of the power amplifier gain switching range will be indirectly Affect the battery life of mobile communication devices.
基於上述目的,本發明揭露了一種功率控制方法,適用於一行動裝置,包括:從一無線通訊網路接收傳送功率控制資訊;根據上述傳送功率控制資訊決定一放大器之一輸出功率範圍;當上述輸出功率範圍小於一功率範圍門檻值時,決定一低增益切換範圍作為上述放大器之一放大器增益切換範圍,其中,上述低增益切換範圍包括一第一上界和一第一下界;當上述輸出功率範圍超出上述功率範圍門檻值時,決定一高增益切換範圍作為上述放大器之上述放大器增益切換範圍,其中,上述高增益切換範圍包括一第二上界和一第二下界,上述第二上界小於上述第一上界,且上述第二下界小於上述第一下界;當一上行訊號之一傳送功率在上述放大器增益切換範圍之內時,使用一第一增益模式放大上述上行訊號;以及當上述上行訊號之上述傳送功率在上述放大器增益切換範圍之外時,使用一第二增益模式放大上述上行訊號。 Based on the above object, the present invention discloses a power control method suitable for a mobile device, comprising: receiving transmission power control information from a wireless communication network; determining an output power range of an amplifier according to the transmission power control information; When the power range is less than a power range threshold, determining a low gain switching range as one of the amplifier gain switching ranges, wherein the low gain switching range includes a first upper bound and a first lower bound; when the output power is When the range exceeds the threshold of the power range, a high gain switching range is determined as the amplifier gain switching range of the amplifier, wherein the high gain switching range includes a second upper bound and a second lower bound, and the second upper bound is smaller than The first upper bound, and the second lower bound is smaller than the first lower bound; when one of the uplink signals transmits power within the amplifier gain switching range, the first gain mode is used to amplify the uplink signal; and when The above transmission power of the uplink signal is in the above amplifier When Yi switching range, using a second gain mode amplifying the uplink signal.
本發明更揭露了一種功率控制方法,適用於一行動裝置,包括:從一記憶體裝置接收內部資訊;根據上述內部資訊決定一放大器之一輸出功率範圍;當上述輸出功率範圍小於一功率範圍門檻值時,決定一低增益切換範圍作為上述放大 器之一放大器增益切換範圍,其中,上述低增益切換範圍包括一第一上界和一第一下界;當上述輸出功率範圍超出上述功率範圍門檻值時,決定一高增益切換範圍作為上述放大器之上述放大器增益切換範圍,其中,上述高增益切換範圍包括一第二上界和一第二下界,上述第二上界小於上述第一上界,且上述第二下界小於上述第一下界;當一上行訊號之一傳送功率在上述放大器增益切換範圍之內時,使用一第一增益模式放大上述上行訊號;以及當上述上行訊號之上述傳送功率在上述放大器增益切換範圍之外時,使用一第二增益模式放大上述上行訊號。 The invention further discloses a power control method, which is applicable to a mobile device, comprising: receiving internal information from a memory device; determining an output power range of an amplifier according to the internal information; and when the output power range is less than a power range threshold When determining the value, determine a low gain switching range as the above amplification The amplifier gain switching range, wherein the low gain switching range includes a first upper bound and a first lower bound; when the output power range exceeds the power range threshold, determining a high gain switching range as the amplifier The amplifier gain switching range, wherein the high gain switching range includes a second upper bound and a second lower bound, the second upper bound is smaller than the first upper bound, and the second lower bound is smaller than the first lower bound; When a transmission power of one of the uplink signals is within the gain switching range of the amplifier, a first gain mode is used to amplify the uplink signal; and when the transmission power of the uplink signal is outside the amplifier gain switching range, a The second gain mode amplifies the above uplink signal.
本發明更揭露了一種行動裝置,能夠調整一增益切換範圍,包括一放大器、一控制器、以及一外部資訊電路。該放大器以一增益模式放大一上行訊號。該控制器從一無線通訊網路接收傳送功率控制資訊。該外部資訊電路根據上述傳送功率控制資訊決定一放大器之一輸出功率範圍。當上述輸出功率範圍小於一功率範圍門檻值時,上述控制器更決定一低增益切換範圍作為上述放大器之一放大器增益切換範圍,其中,上述低增益切換範圍包括一第一上界和一第一下界。當上述輸出功率範圍超出上述功率範圍門檻值時,上述控制器更決定一高增益切換範圍作為上述放大器之上述放大器增益切換範圍,其中,上述高增益切換範圍包括一第二上界和一第二下界,上述第二上界小於上述第一上界,且上述第二下界小於上述第一下界。當一上行訊號之一傳送功率在上述放大器增益切換範圍之內時,上述控制器更選擇一第一增益模式做為上述放 大器之上述增益模式。當上述上行訊號之上述傳送功率在上述放大器增益切換範圍之外時,上述控制器更選擇一第二增益模式做為上述放大器之上述增益模式。 The present invention further discloses a mobile device capable of adjusting a gain switching range, including an amplifier, a controller, and an external information circuit. The amplifier amplifies an up signal in a gain mode. The controller receives transmission power control information from a wireless communication network. The external information circuit determines an output power range of an amplifier based on the transmission power control information. When the output power range is less than a power range threshold, the controller further determines a low gain switching range as one of the amplifier gain switching ranges, wherein the low gain switching range includes a first upper bound and a first Lower bound. When the output power range exceeds the power range threshold, the controller further determines a high gain switching range as the amplifier gain switching range of the amplifier, wherein the high gain switching range includes a second upper bound and a second a lower boundary, the second upper boundary being smaller than the first upper boundary, and the second lower boundary being smaller than the first lower boundary. When one of the uplink signals transmits power within the gain switching range of the amplifier, the controller further selects a first gain mode as the above The above gain mode of the device. When the transmission power of the uplink signal is outside the amplifier gain switching range, the controller further selects a second gain mode as the gain mode of the amplifier.
本發明更揭露了一種行動裝置,能夠調整一增益切換範圍,包括一放大器、一記憶體、一內部資訊電路、以及一控制器。該放大器以一增益模式放大一上行訊號。該記憶體儲存內部資訊。該內部資訊電路從上述記憶體接收內部資訊,且根據上述內部資訊決定一放大器之一輸出功率範圍。該控制器當上述輸出功率範圍小於一功率範圍門檻值時,決定一低增益切換範圍作為上述放大器之一放大器增益切換範圍,其中,上述低增益切換範圍包括一第一上界和一第一下界;當上述輸出功率範圍超出上述功率範圍門檻值時,決定一高增益切換範圍作為上述放大器之上述放大器增益切換範圍,其中,上述高增益切換範圍包括一第二上界和一第二下界,上述第二上界小於上述第一上界,且上述第二下界小於上述第一下界,當一上行訊號之一傳送功率在上述放大器增益切換範圍之內時,選擇一第一增益模式做為上述放大器之上述增益模式,以及當上述上行訊號之上述傳送功率在上述放大器增益切換範圍之外時,選擇一第二增益模式做為上述放大器之上述增益模式。 The present invention further discloses a mobile device capable of adjusting a gain switching range, including an amplifier, a memory, an internal information circuit, and a controller. The amplifier amplifies an up signal in a gain mode. This memory stores internal information. The internal information circuit receives internal information from the memory and determines an output power range of an amplifier based on the internal information. The controller determines a low gain switching range as one of the amplifier gain switching ranges when the output power range is less than a power range threshold, wherein the low gain switching range includes a first upper bound and a first lower When the output power range exceeds the power range threshold, determining a high gain switching range as the amplifier gain switching range of the amplifier, wherein the high gain switching range includes a second upper bound and a second lower bound, The second upper bound is smaller than the first upper bound, and the second lower bound is smaller than the first lower bound. When one of the uplink signals transmits power within the amplifier gain switching range, a first gain mode is selected as The gain mode of the amplifier, and when the transmission power of the uplink signal is outside the amplifier gain switching range, selecting a second gain mode as the gain mode of the amplifier.
本發明更揭露了一種功率控制系統,包括第一和第二無線通訊網路和一行動裝置。該第一和第二無線通訊網路分別廣播第一和第二傳送功率控制資訊。該一行動裝置,從上述第一和第二無線通訊網路中決定一有效網路,接收由上述有 效網路廣播之上述第一和第二傳送功率控制資訊之一者,根據上述接收之上述第一和第二傳送功率控制資訊之一者決定一放大器之一輸出功率範圍,當上述輸出功率範圍小於一功率範圍門檻值時,決定一低增益切換範圍作為上述放大器之一放大器增益切換範圍,其中,上述低增益切換範圍包括一第一上界和一第一下界,當上述輸出功率範圍超出上述功率範圍門檻值時,決定一高增益切換範圍作為上述放大器之上述放大器增益切換範圍,其中,上述高增益切換範圍包括一第二上界和一第二下界,上述第二上界小於上述第一上界,且上述第二下界小於上述第一下界,當一上行訊號之一傳送功率在上述放大器增益切換範圍之內時,以一第一增益模式放大上述上行訊號;以及當上述上行訊號之上述傳送功率在上述放大器增益切換範圍之外時,以一第二增益模式放大上述上行訊號。 The invention further discloses a power control system comprising first and second wireless communication networks and a mobile device. The first and second wireless communication networks broadcast the first and second transmission power control information, respectively. The mobile device determines an active network from the first and second wireless communication networks, and receives the And one of the first and second transmission power control information of the network broadcast, determining an output power range of an amplifier according to one of the received first and second transmission power control information, when the output power range When less than a power range threshold, a low gain switching range is determined as one of the amplifier gain switching ranges, wherein the low gain switching range includes a first upper bound and a first lower bound when the output power range exceeds Determining a high gain switching range as the amplifier gain switching range of the amplifier, wherein the high gain switching range includes a second upper bound and a second lower bound, wherein the second upper bound is smaller than the foregoing An upper bound, wherein the second lower bound is smaller than the first lower bound, and when one of the uplink signals transmits power within the amplifier gain switching range, the uplink signal is amplified by a first gain mode; and when the uplink signal is When the above transmission power is outside the above-mentioned amplifier gain switching range, a second gain is used. The uplink signal amplification method.
2‧‧‧通訊裝置 2‧‧‧Communication device
20‧‧‧RF電路 20‧‧‧RF circuit
200‧‧‧PA 200‧‧‧PA
202‧‧‧RF前端電路 202‧‧‧RF front-end circuit
22‧‧‧控制電路 22‧‧‧Control circuit
220‧‧‧控制器 220‧‧‧ Controller
222‧‧‧通訊協定模組 222‧‧‧Communication Agreement Module
224‧‧‧外部資訊模組 224‧‧‧External information module
24‧‧‧記憶體 24‧‧‧ memory
240‧‧‧使用者應用程式 240‧‧‧User Application
242‧‧‧內部資訊程式 242‧‧‧Internal information program
26‧‧‧匯流排 26‧‧‧ Busbar
S300、S302...S326‧‧‧步驟 S300, S302...S326‧‧‧ steps
S500、S502...S510‧‧‧步驟 S500, S502...S510‧‧‧ steps
6‧‧‧異構網路 6‧‧‧ Heterogeneous network
60‧‧‧WLAN 60‧‧‧WLAN
62‧‧‧WPAN 62‧‧‧WPAN
64‧‧‧無線裝置 64‧‧‧Wireless devices
SWLAN‧‧‧WLAN訊號 S WLAN ‧‧‧WLAN signal
SWPAN‧‧‧WPAN訊號 S WPAN ‧‧‧WPAN signal
8‧‧‧行動裝置 8‧‧‧Mobile devices
80‧‧‧數位類比轉換器 80‧‧‧Digital Analog Converter
800‧‧‧電路A 800‧‧‧Circuit A
802‧‧‧電路B 802‧‧‧ Circuit B
81‧‧‧加法器 81‧‧‧Adder
82‧‧‧混頻器 82‧‧‧ Mixer
83‧‧‧程控增益放大器 83‧‧‧Programmable Gain Amplifier
84‧‧‧濾波器和天線切換器 84‧‧‧Filter and antenna switcher
85‧‧‧控制電路 85‧‧‧Control circuit
86‧‧‧本地震盪器 86‧‧‧The Earthquake
850‧‧‧控制器 850‧‧‧ Controller
852‧‧‧內部資訊電路 852‧‧‧Internal information circuit
854‧‧‧外部資訊電路 854‧‧‧External information circuit
87‧‧‧頻率合成器 87‧‧‧ frequency synthesizer
88a、88b‧‧‧天線 88a, 88b‧‧‧ antenna
89‧‧‧記憶體裝置 89‧‧‧ memory device
890‧‧‧外部資訊 890‧‧‧External information
892‧‧‧內部資訊 892‧‧‧Internal information
90‧‧‧數位類比轉換器 90‧‧‧Digital Analog Converter
900‧‧‧電路A 900‧‧‧Circuit A
902‧‧‧電路B 902‧‧‧Circuit B
91a、91b‧‧‧混頻器 91a, 91b‧‧‧ mixer
92a、92b‧‧‧程控增益放大器 92a, 92b‧‧‧ Programmable Gain Amplifier
93‧‧‧濾波器和天線切換器 93‧‧‧Filter and Antenna Switcher
94a、94b‧‧‧天線 94a, 94b‧‧‧Antenna
95‧‧‧控制電路 95‧‧‧Control circuit
950‧‧‧控制器 950‧‧‧ Controller
952‧‧‧內部資訊電路 952‧‧‧Internal information circuit
954‧‧‧外部資訊電路 954‧‧‧External information circuit
96‧‧‧本地震盪器 96‧‧‧The Earthquake
97‧‧‧頻率合成器 97‧‧‧ frequency synthesizer
99‧‧‧記憶體裝置 99‧‧‧ memory device
990‧‧‧外部資訊 990‧‧‧External information
992‧‧‧內部資訊 992‧‧‧Internal information
10‧‧‧功率控制方法 10‧‧‧Power control method
S1000、S1002...S1016‧‧‧步驟 S1000, S1002...S1016‧‧‧ steps
11‧‧‧功率控制方法 11‧‧‧Power control method
S1100、S1102...S1116‧‧‧步驟 S1100, S1102...S1116‧‧‧ steps
第1圖係顯示十字路口的街道環境,用於顯示本發明實施例中之一種定位方法。 1 is a street environment showing an intersection for displaying a positioning method in an embodiment of the present invention.
第2圖係為本發明實施例中一種定位例子的示意圖。 FIG. 2 is a schematic diagram of a positioning example in the embodiment of the present invention.
第3圖係為本發明實施例中另一種定位例子的示意圖。 Figure 3 is a schematic diagram of another positioning example in the embodiment of the present invention.
第4圖係為本發明實施例中一種BLE裝置4的方塊圖。 Figure 4 is a block diagram of a BLE device 4 in accordance with an embodiment of the present invention.
第5圖係為本發明實施例中一種定位方法5的流程圖。 Figure 5 is a flow chart of a positioning method 5 in the embodiment of the present invention.
第6圖係為本發明實施例中另一種定位方法6的流程圖。 Figure 6 is a flow chart of another positioning method 6 in the embodiment of the present invention.
第7圖顯示不同增益切換範圍的詳細運作方式。 Figure 7 shows the detailed operation of the different gain switching ranges.
第8圖係顯示本發明實施例中一種行動裝置8的區塊圖。 Figure 8 is a block diagram showing a mobile device 8 in an embodiment of the present invention.
第9圖係顯示本發明實施例中另一種行動裝置9的區塊圖。 Fig. 9 is a block diagram showing another mobile device 9 in the embodiment of the present invention.
第10圖係顯示本發明實施例中另一種功率控制方法10的流程圖。 Figure 10 is a flow chart showing another power control method 10 in an embodiment of the present invention.
第11圖係顯示本發明實施例中另一種功率控制方法11的流程圖。 Figure 11 is a flow chart showing another power control method 11 in the embodiment of the present invention.
在此必須說明的是,於下揭露內容中所提出之不同實施例或範例,係用以說明本發明所揭示之不同技術特徵,其所描述之特定範例或排列係用以簡化本發明,然非用以限定本發明。此外,在不同實施例或範例中可能重覆使用相同之參考數字與符號,此等重覆使用之參考數字與符號係用以說明本發明所揭示之內容,而非用以表示不同實施例或範例間之關係。 The various embodiments and examples set forth in the following disclosure are intended to illustrate various technical features disclosed herein, and the specific examples or arrangements described herein are used to simplify the invention. It is not intended to limit the invention. In addition, the same reference numerals and symbols may be used in the different embodiments or examples, and the repeated reference numerals and symbols are used to illustrate the disclosure of the present invention, and are not intended to represent different embodiments or The relationship between the examples.
實施例中的各元件之配置係為說明之用,並非用以限制本發明。 The arrangement of the various elements in the embodiments is for illustrative purposes and is not intended to limit the invention.
第1圖係顯示本發明實施例中通訊裝置內功率放大器之增益模式的切換方法的示意圖,其中橫軸代表功率放大器的功率,且縱軸代表通訊裝置的功率。實施例中顯示功率放大器PA具有兩種增益模式,包括低增益模式10和高增益模式12。功率放大器PA能由3種增益切換範圍1、S2和S3之其一控制而於低增益模式10和高增益模式12之間切換,並且根據所切換的低增益模式10或高增益模式12放大一上行訊號的功率以在合適的通訊通道中推出傳該上行訊號。上述通訊裝置能根據上行訊號所需輸出功率的特性而選用上述3種增益切換 範圍1、S2和S3之其一,進而控制上述功率放大器的增益模式。通訊裝置可為智能手機、平板電腦、手提電腦及其他具有無線通訊功能的電子裝置。 1 is a schematic diagram showing a method of switching a gain mode of a power amplifier in a communication device in an embodiment of the present invention, wherein a horizontal axis represents power of a power amplifier, and a vertical axis represents power of a communication device. The power amplifier PA is shown in the embodiment to have two gain modes, including a low gain mode 10 and a high gain mode 12. The power amplifier PA can be switched between the low gain mode 10 and the high gain mode 12 by one of the three gain switching ranges 1, S2 and S3, and is amplified according to the switched low gain mode 10 or the high gain mode 12. The power of the uplink signal is used to push out the uplink signal in a suitable communication channel. The above communication device can select the above three kinds of gain switching according to the characteristics of the output power required for the uplink signal. One of the ranges 1, S2 and S3, which in turn controls the gain mode of the power amplifier described above. The communication device can be a smart phone, a tablet computer, a laptop computer, and other electronic devices with wireless communication functions.
當射頻發射電路的設計架構已經決定後,即可決定發射電路的可能增益切換範圍。功率放大器之增益切換範圍落在功率放大器之增益模式切換點的可調範圍內,即P1到P6的範圍內,而PA增益切換範圍的位置又大致可分為上述3種增益切換範圍1、S2和S3。 When the design architecture of the RF transmit circuit has been determined, the possible gain switching range of the transmit circuit can be determined. The gain switching range of the power amplifier falls within the adjustable range of the gain mode switching point of the power amplifier, that is, the range of P1 to P6, and the position of the PA gain switching range can be roughly divided into the above three kinds of gain switching range 1, S2. And S3.
在增益切換範圍1中,當功率放大器PA使用低增益模式10而所需的PA功率超過功率P2時,功率放大器PA會切換至高增益模式12,藉以放大上行訊號的功率。當功率放大器PA使用高增益模式12而所需的PA功率小於功率P1時,功率放大器PA會切換至低增益模式10,藉以減少放大器操作的功率。和其他增益切換範圍2和S3相比,由於增益模式切換點提早落在高增益模式12的輸出,此部份設計雖提供RF功率放大器更大的線性放大空間,卻導致PA操作時產生增加的消耗功率。增益切換範圍1適用於無線通訊系統,該無線通訊系統可擁有較高的調變技術,例如16QAM或是64QAM、較高的傳輸速率或頻寬,例如多載波寬頻分碼多工(Wideband Code Division Multiple Access,以下稱為W-CDMA)或是先進長期演進技術(Long Term Evolution-Advanced,以下稱為LTE-A)的載波聚合(Carrier Aggregation)、子載波(Sub-載波)通道多工之功能,例如OFDM或多層調變器(Multi-Layer Modulator)。增益切換範圍1適用的通訊技術可例如為3GPP 的Rel-5、Rel-6、Rel-7版本(W-CDMA)、Rel-8、Rel-9版本(Long Term Evolution,以下稱為LTE)和Rel-10、Rel-11等之後的版本(LTE-A)。類似的通訊系統也包含IEEE802.11n/ac/ad等具有高速傳輸的發射機。 In the gain switching range 1, when the power amplifier PA uses the low gain mode 10 and the required PA power exceeds the power P2, the power amplifier PA switches to the high gain mode 12, thereby amplifying the power of the up signal. When the power amplifier PA uses the high gain mode 12 and the required PA power is less than the power P1, the power amplifier PA switches to the low gain mode 10, thereby reducing the power of the amplifier operation. Compared with other gain switching ranges 2 and S3, since the gain mode switching point falls early in the output of the high gain mode 12, this part of the design provides a larger linear amplification space for the RF power amplifier, which results in an increase in the PA operation. Power consumption. Gain switching range 1 is suitable for wireless communication systems. The wireless communication system can have high modulation technology, such as 16QAM or 64QAM, high transmission rate or bandwidth, such as multi-carrier wideband code division multiplexing (Wideband Code Division). Multiple Access, hereinafter referred to as W-CDMA) or Advanced Term Evolution-Advanced (hereinafter referred to as LTE-A) carrier aggregation (Carrier Aggregation), subcarrier (Sub-carrier) channel multiplexing For example, OFDM or Multi-Layer Modulator. The communication technology applicable to the gain switching range 1 can be, for example, 3GPP Rel-5, Rel-6, Rel-7 (W-CDMA), Rel-8, Rel-9 (Long Term Evolution, hereinafter referred to as LTE) and Rel-10, Rel-11, etc. ( LTE-A). Similar communication systems also include transmitters with high speed transmission such as IEEE 802.11n/ac/ad.
在增益切換範圍2中,當功率放大器PA使用低增益模式10而所需的PA功率超過功率P6時,功率放大器PA會切換至高增益模式12,藉以放大上行訊號的功率。當功率放大器PA使用高增益模式12而所需的PA功率小於功率P5時,功率放大器PA會切換至低增益模式10,藉以減少放大器操作的功率。相較於增益切換範圍1,增益切換範圍2的增益模式落在低增益模式10的比例變高,使得PA操作所需的功耗減少,但此情形將使功率放大器PA的線性操作空間變小。特別在某些信號傳輸模式時易產生RF訊號失真。例如,在某些特定的實體層或第1層信號調變組合以及無線資源排序(Radio Resource Scheduling)易產生較大的峰值對均值功率比(Peak-to-Average-Ratio,以下稱為PAPR)。增益切換範圍2適用於無線通訊系統,具有較低的傳輸速率以及調變技術,例如BPSK或是QPSK調變技術及較少實體層通道多工技術使用。 In the gain switching range 2, when the power amplifier PA uses the low gain mode 10 and the required PA power exceeds the power P6, the power amplifier PA switches to the high gain mode 12, thereby amplifying the power of the up signal. When the power amplifier PA uses the high gain mode 12 and the required PA power is less than the power P5, the power amplifier PA switches to the low gain mode 10, thereby reducing the power of the amplifier operation. Compared with the gain switching range 1, the gain mode of the gain switching range 2 falls in the low gain mode 10, so that the power consumption required for the PA operation is reduced, but this situation will make the linear operation space of the power amplifier PA smaller. . Especially in some signal transmission modes, it is easy to generate RF signal distortion. For example, in certain specific physical layer or layer 1 signal modulation combination and radio resource scheduling (Radio Resource Scheduling), it is easy to generate a large peak-to-average power ratio (Peak-to-Average-Ratio, hereinafter referred to as PAPR). . Gain switching range 2 is suitable for wireless communication systems, with low transmission rate and modulation technology, such as BPSK or QPSK modulation technology and less physical layer channel multiplexing technology.
在增益切換範圍3中,避免增益切換範圍1的過度功率消耗,以及增益切換範圍2的PA線性空間過小,介於增益切換範圍1與增益切換範圍2的增益切換範圍3提供發射電路設計者一個彈性且折衷的選擇。 In the gain switching range 3, the excessive power consumption of the gain switching range 1 is avoided, and the PA linear space of the gain switching range 2 is too small, and the gain switching range 3 between the gain switching range 1 and the gain switching range 2 provides a transmission circuit designer. Flexible and compromised choices.
本發明實施例可改善通訊裝置的電池壽命,提出如何有彈性且動態調整PA增益切換範圍,使得電池壽命可以 延伸。 The embodiment of the invention can improve the battery life of the communication device, and propose how to flexibly and dynamically adjust the PA gain switching range, so that the battery life can be extend.
第2圖係顯示本發明實施例中一種通訊裝置2的方塊圖,包括RF電路20、控制電路22、記憶體24和匯流排[廣義的一種或多種傳輸介面]26。RF電路20、控制電路22和記憶體24可藉由匯流排26互相溝通以及傳遞資料。通訊裝置2可實現第1圖中功率放大器多個切換範圍的機制。特別是,通訊裝置2能夠根據估計功率放大器的所需功率範圍,而後在根據估計出之所需功率範圍從多個切換範圍中選擇一個適用的切換範圍讓功率放大器使用。 2 is a block diagram showing a communication device 2 in an embodiment of the present invention, including an RF circuit 20, a control circuit 22, a memory 24, and a bus bar [one or more transmission interfaces] in a broad sense. The RF circuit 20, the control circuit 22, and the memory 24 can communicate with each other and transfer data by the bus bar 26. The communication device 2 can implement the mechanism of multiple switching ranges of the power amplifier in FIG. In particular, the communication device 2 is capable of using the power amplifier according to the estimated power range of the power amplifier and then selecting a suitable switching range from the plurality of switching ranges based on the estimated required power range.
RF電路20用於由空氣介面中傳送上行訊號及接收下行訊號。控制電路22用於各種基頻訊號處理、通訊協定處理器[廣義來說就是通訊模式m或通訊CPU模組],包括判定網路系統分配給通訊裝置2的無線資源以及環境周圍的訊號品質。記憶體24[主要處理OS與使用者APP的CPU模組]用於儲存程式碼以及資料,收集在通訊裝置2上使用無線模組的時間、地點、相關軟體關的使用,並針對與PA增益切換範圍或輸出功率相關的訊息進行適應性調整與分析。控制電路22與記憶體24分別提供對於外部資訊功能以及內部資訊功能的適應性PA增益切換範圍調整,使得功率放大器PA200的PA增益切換範圍可依照實際使用者狀態或是無線環境的變化進行以電池使用時間為目的的最佳化調整。 The RF circuit 20 is configured to transmit an uplink signal and receive a downlink signal from an air interface. The control circuit 22 is used for various baseband signal processing, communication protocol processors [broadly speaking, the communication mode m or the communication CPU module], and includes determining the wireless resources allocated by the network system to the communication device 2 and the signal quality around the environment. The memory 24 [mainly processing the CPU module of the OS and the user APP] is used for storing the code and the data, collecting the time, the location of the use of the wireless module on the communication device 2, the use of the related software, and the gain with the PA. Adaptation and analysis of switching range or output power related information. The control circuit 22 and the memory 24 respectively provide adaptive PA gain switching range adjustment for the external information function and the internal information function, so that the PA gain switching range of the power amplifier PA200 can be performed according to the actual user state or the change of the wireless environment. Optimized adjustments for time use.
RF電路20包括功率放大器PA200和RF前端電路202。RF電路20可更包括匹配電路、各種濾波器以及線路佈線(未圖示)。針對RF電路20,在硬體架構底定後,即可在 每次開機或出廠時透過RF校正的方式決定一組功率放大器增益切換範圍以獲得穩定的RF電路效能。功率放大器PA200具有二或多種增益模式,例如,高、中及低增益模式。每種增益模式都具有二或多種增益切換範圍,該增益切換範圍可由控制電路22所選擇控制。例如,低增益模式之具有兩種增益切換範圍可切換到中增益模式,其中一種增益切換範圍可以產生較大的功率放大器的線性空間,另一種增益切換範圍可以避免過度的功率消耗。在一些實施例中,功率放大器PA200能從控制電路22接收增益控制訊號,以從多種增益模式中選擇一種用來放大上行訊號之功率並傳送放大的上行訊號到接收機、基地台以及網路系統端。 The RF circuit 20 includes a power amplifier PA200 and an RF front end circuit 202. The RF circuit 20 may further include matching circuits, various filters, and line wiring (not shown). For the RF circuit 20, after the hardware architecture is fixed, Each set of power amplifier gain switching range is determined by RF correction every time it is turned on or off the factory to obtain stable RF circuit performance. The power amplifier PA200 has two or more gain modes, such as high, medium, and low gain modes. Each gain mode has two or more gain switching ranges that can be selected for control by control circuitry 22. For example, the low gain mode has two gain switching ranges that can be switched to the medium gain mode, where one gain switching range can produce a larger linear space of the power amplifier, and the other gain switching range can avoid excessive power consumption. In some embodiments, the power amplifier PA200 can receive a gain control signal from the control circuit 22 to select one of a plurality of gain modes for amplifying the power of the uplink signal and transmitting the amplified uplink signal to the receiver, the base station, and the network system. end.
控制電路22包括控制器220、通訊協定模組222和外部資訊模組224,用於所有和通訊裝置2外部環境相關的資訊或資料處理。控制電路22根據處理過的資訊或資料能估計上行訊號的輸出功率,進而藉由估計出的上行訊號輸出功率來決定PA增益切換範圍。上述外部環境相關的資訊或資料包括網路資源分配以及無線通道環境。網路系統端會將有限的無線資源,包括無線資源管理(Radio Resource Management,以下稱為RRM)、傳送功率控制(Transmit Power Control,以下稱為TPC)、服務質量(Quality of Service,以下稱為QoS)分配給各個範圍內的無線通訊裝置。控制電路22會隨分配到的無線資源而估計出不同的上行訊號的輸出功率。例如,網路系統端可分配多個載波、某個傳送功率、即時的服務品質給通訊裝置2,而通訊協定模組222可以解讀網路系統端寄送的系 統訊息而獲得上述的載波、傳送功率和服務品質資訊,接著控制器220可根據所獲得的的載波、傳送功率和服務品質資訊而估計上行訊號的輸出功率以及上行訊號輸出功率的分布。在一些實施例中,通訊協定模組222可和網路系統以共同的通訊協定溝通,進而調整PA增益切換模式來改善電池壽命。另外,由於網路系統同時存在各種種類的基地台,包括大型基地台(Macrocell)、微型基地台(Microcell)、特微型基地台(Picocell)、毫微微蜂巢型基地台(Femtocell)或其他種類的基地台,以及網路系統的服務版本差異,無線通道的干擾將隨使用環境而有所不同,為此,控制電路22能藉由外部資訊模組224計算PA增益切換範圍與無線通道環境的關係而計算訊號對干擾及雜訊比(Signal to Interference and Noise Ratio,以下稱為SINR),接著控制器220可根據計算出之SINR而估計上行訊號的輸出功率以及上行訊號輸出功率的分布。最後,控制器220能根據估計之上行訊號輸出功率的分布而決定功率放大器PA200的增益切換範圍,並能根據所決定的增益切換範圍和上行訊號的輸出功率決定一種PA增益模式,並將決定之PA增益模式以增益控制訊號的方式送到功率放大器PA200來放大上行訊號的功率。例如,當上行訊號的輸出功率超過增益切換範圍的上限切換值時,控制器220可藉由增益控制訊號將功率放大器PA200切換到比目前更上一級的增益模式。當上行訊號的輸出功率小於增益切換範圍的下限切換值時,控制器220可藉由增益控制訊號將功率放大器PA200切換到比目前更下一級的增益模式。當上行訊號的輸出功率在上述上限和下限切 換值之間時,功率放大器PA200可維持目前的增益模式。通訊協定模組222和外部資訊模組224可以是數位電路[DSP]或是具有相關驅動程式的記憶體。上述上行訊號輸出功率的分布以及對應的增益切換範圍可以以查找表的方式記錄於控制電路22內部的或其他位置的記憶體中。 The control circuit 22 includes a controller 220, a communication protocol module 222, and an external information module 224 for all information or data processing related to the external environment of the communication device 2. The control circuit 22 can estimate the output power of the uplink signal based on the processed information or data, and determine the PA gain switching range by the estimated uplink signal output power. The information or materials related to the above external environment include network resource allocation and wireless channel environment. The network system side will have limited radio resources, including Radio Resource Management (hereinafter referred to as RRM), Transmit Power Control (hereinafter referred to as TPC), and Quality of Service (hereinafter referred to as Quality of Service). QoS) is assigned to wireless communication devices in various ranges. The control circuit 22 estimates the output power of the different uplink signals with the assigned radio resources. For example, the network system side can allocate multiple carriers, a certain transmission power, and immediate service quality to the communication device 2, and the communication protocol module 222 can interpret the system sent by the network system side. The carrier, the transmission power and the quality of service information are obtained by the unified message, and then the controller 220 can estimate the output power of the uplink signal and the distribution of the uplink signal output power according to the obtained carrier, transmission power and service quality information. In some embodiments, the protocol module 222 can communicate with the network system in a common communication protocol to adjust the PA gain switching mode to improve battery life. In addition, due to the existence of various types of base stations in the network system, including Macrocells, Microcells, Picocells, Femtocells, or other types of The difference between the base station and the service version of the network system, the interference of the wireless channel will vary with the use environment. For this reason, the control circuit 22 can calculate the relationship between the PA gain switching range and the wireless channel environment by the external information module 224. The signal to interference and noise ratio (hereinafter referred to as SINR) is calculated, and then the controller 220 can estimate the output power of the uplink signal and the distribution of the uplink signal output power according to the calculated SINR. Finally, the controller 220 can determine the gain switching range of the power amplifier PA200 according to the estimated distribution of the uplink signal output power, and can determine a PA gain mode according to the determined gain switching range and the output power of the uplink signal, and determine the The PA gain mode is sent to the power amplifier PA200 in the form of a gain control signal to amplify the power of the uplink signal. For example, when the output power of the uplink signal exceeds the upper limit switching value of the gain switching range, the controller 220 can switch the power amplifier PA200 to a gain mode higher than the current level by the gain control signal. When the output power of the uplink signal is less than the lower limit switching value of the gain switching range, the controller 220 can switch the power amplifier PA200 to the gain mode of the next stage by the gain control signal. When the output power of the uplink signal is cut at the above upper and lower limits The power amplifier PA200 maintains the current gain mode when switching between values. The protocol module 222 and the external information module 224 can be digital circuits [DSP] or memory with associated drivers. The distribution of the uplink signal output power and the corresponding gain switching range may be recorded in a memory inside the control circuit 22 or at other locations in a look-up table.
記憶體24包括使用者應用程式240和內部資訊程式242,用於所有和通訊裝置2內部資訊相關的資料處理。使用者應用程式240和內部資訊程式242可被一處理器或控制器(未圖示)存取以及根據程式碼加以執行。在某些實施例中,控制電路22內的控制器220可從記憶體24中存取使用者應用程式240和內部資訊程式242並且執行其程式碼,收集在通訊裝置2上使用無線模組的時間、地點、相關軟體的使用,並針對與PA增益切換範圍或輸出功率相關的訊息進行適應性調整與分析。例如,使用者可在使用者應用程式240針對某個時間、某個地點、某種網路服務或某個相關軟體輸入上傳速度、頻寬或資料流量限制,接著控制器220可根據輸入的的上傳速度、頻寬或資料流量限制而估計上行訊號的輸出功率以及上行訊號輸出功率的分布,進而根據估計之上行訊號輸出功率的分布而決定功率放大器PA200的增益切換範圍,以及根據所決定的增益切換範圍和上行訊號的輸出功率決定功率放大器PA200使用的PA增益模式。控制器220可從記憶體24中存取內部資訊程式242而針對時間、地點、相關服務及軟體進行統計分析,獲得對應的增益切換範圍。當通訊裝置2下次需要網路服務時,內部資訊程式242便可根據上述分析過的資料而直接找到 對應的增益切換範圍讓控制器220使用,根據對應的增益切換範圍和上行訊號的輸出功率決定一種PA增益模式,並將決定之PA增益模式以增益控制訊號的方式送到功率放大器PA200來放大上行訊號的功率。上述上行訊號輸出功率的分布以及對應的增益切換範圍可以以查找表的方式記錄於記憶體24或其他位置的記憶體中。 The memory 24 includes a user application 240 and an internal information program 242 for all data processing related to the internal information of the communication device 2. User application 240 and internal information program 242 can be accessed by a processor or controller (not shown) and executed in accordance with the code. In some embodiments, the controller 220 in the control circuit 22 can access the user application 240 and the internal information program 242 from the memory 24 and execute the code thereof, and collect the wireless module on the communication device 2. Time, location, use of related software, and adaptive adjustment and analysis of messages related to PA gain switching range or output power. For example, the user can input an upload speed, bandwidth, or data flow limit for the user application 240 for a certain time, a certain place, a certain network service, or a related software, and then the controller 220 can be based on the input. Estimating the output power of the uplink signal and the distribution of the uplink signal output power by uploading the speed, the bandwidth, or the data flow limit, and determining the gain switching range of the power amplifier PA200 according to the estimated distribution of the uplink signal output power, and determining the gain according to the determined The switching range and the output power of the uplink signal determine the PA gain mode used by the power amplifier PA200. The controller 220 can access the internal information program 242 from the memory 24 to perform statistical analysis on time, location, related services, and software to obtain a corresponding gain switching range. When the communication device 2 needs the network service next time, the internal information program 242 can directly find the data according to the above analysis. The corresponding gain switching range is used by the controller 220 to determine a PA gain mode according to the corresponding gain switching range and the output power of the uplink signal, and the determined PA gain mode is sent to the power amplifier PA200 as a gain control signal to amplify the uplink. The power of the signal. The distribution of the uplink signal output power and the corresponding gain switching range may be recorded in the memory 24 or other locations in a look-up table.
第3圖係顯示本發明實施例中一種功率放大器之增益模式的切換方法3的流程圖,使用第2圖之通訊裝置2。 Fig. 3 is a flow chart showing a method 3 for switching the gain mode of a power amplifier in the embodiment of the present invention, using the communication device 2 of Fig. 2.
在通訊裝置2初始切換方法3後,通訊裝置2能夠依據使用者習慣或需求來使用內部資訊功能或外部資訊功能來決定增益切換範圍。針對內部資訊功能來說,控制器220能檢查內部資訊功能選項是否已經啟動(S300)。如果尚未啟動,則控制器220持續或定時繼續檢查內部資訊功能選項的狀態(S300)。 After the initial switching method 3 of the communication device 2, the communication device 2 can use the internal information function or the external information function to determine the gain switching range according to user habits or needs. For the internal information function, the controller 220 can check whether the internal information function option has been activated (S300). If not yet started, the controller 220 continues to check the status of the internal information function option continuously or periodically (S300).
如果已經啟動,控制器220便能根據內部資訊所產生的上行訊號,進而決定代表上行訊號輸出功率分布的一種PA參數(S302)。上述內部資訊可由控制器220執行記憶體內部的使用者應用程式240和內部資訊程式242產生。例如,使用者應用程式240可以用於接收使用者輸入的內部資訊,例如上傳速度、頻寬或資料流量限制,控制器220能根據輸入的內部資訊同時產生一或多個數位輸出資料,並將所有產生的數位輸出資料相加以估計第一PA參數。第一PA參數可以是所有數位輸出資料的功率相加值,並且轉為dBm的數值或以數位量化的單位表示。在一段時間之後,控制器220可以獲得代 表上行訊號輸出功率分布的第一PA參數分布,如第4圖所示,係顯示本發明實施例中功率放大器之PA參數分布的示意圖,包括負載1及負載2兩種上行訊號負載以dBm表示,並且PA參數分布直接對應到上行訊號所需功率的分布。每種負載都包括PA-參數範圍、平均值、PA+參數範圍以及前端功率損耗(FE Loss)。PA-參數範圍為PA參數的下限值到所有PA參數平均值的範圍,而PA+參數範圍為PA參數的上限值到所有PA參數平均值的範圍。前端功率損耗係上行訊號經過RF電路20,包括RF前端電路202所產生的功率損耗。 If it has been activated, the controller 220 can determine a PA parameter representing the output power distribution of the uplink signal based on the uplink signal generated by the internal information (S302). The internal information may be generated by the controller 220 executing the user application 240 and the internal information program 242 inside the memory. For example, the user application 240 can be configured to receive internal information input by the user, such as upload speed, bandwidth, or data flow limit, and the controller 220 can simultaneously generate one or more digital output data according to the input internal information, and All generated digital output data are added to estimate the first PA parameter. The first PA parameter may be the power added value of all digital output data and is converted to a value of dBm or expressed in units of digit quantization. After a period of time, the controller 220 can obtain a generation The first PA parameter distribution of the output power distribution of the table uplink signal, as shown in FIG. 4, is a schematic diagram showing the PA parameter distribution of the power amplifier in the embodiment of the present invention, including load 1 and load 2, and the two uplink signal loads are expressed in dBm. And the PA parameter distribution directly corresponds to the distribution of power required for the uplink signal. Each load includes the PA-parameter range, average, PA+ parameter range, and front-end power loss (FE Loss). The PA-parameter range is the range from the lower limit of the PA parameter to the average of all PA parameters, while the PA+ parameter range is the range from the upper limit of the PA parameter to the average of all PA parameters. The front end power loss is the upstream signal passing through the RF circuit 20, including the power loss generated by the RF front end circuit 202.
在產生如第4圖所示之PA參數分布表示後,控制器220能根據PA參數的分布而決定第一增益切換範圍(S304)。例如,當第一PA參數的分布如第4圖的負載1時,因為PA參數分布跨越的是小範圍PA2~PA3,控制器220可以選擇第1圖中的增益切換範圍2作為第一增益切換範圍,使功率放大器PA200有比其他增益切換範圍有較多的時間以低增益模式放大上行訊號。當第一PA參數的分布如第4圖的負載2時,因為PA參數分布跨越的是大範圍PA1~PA3,控制器220可以選擇第1圖中的增益切換範圍1作為第一增益切換範圍,使功率放大器PA200有比其他增益切換範圍有較多的時間以高增益模式放大上行訊號。在其他實施例中,控制器220能根據PA+參數的分布而決定第一增益切換範圍。PA+參數的分布範圍越小,控制器220決定的第一增益切換範圍會有越多時間在較低的增益模式之下。PA+參數的分布範圍越大,控制器220決定的第一增益切換範圍會有越多時間在較高的增益模式之 下。 After generating the PA parameter distribution representation as shown in FIG. 4, the controller 220 can determine the first gain switching range based on the distribution of the PA parameters (S304). For example, when the distribution of the first PA parameter is the load 1 of FIG. 4, since the PA parameter distribution spans the small range PA2~PA3, the controller 220 may select the gain switching range 2 in FIG. 1 as the first gain switching. The range allows the power amplifier PA200 to have more time than other gain switching ranges to amplify the up signal in the low gain mode. When the distribution of the first PA parameter is the load 2 of FIG. 4, since the PA parameter distribution spans the wide range PA1~PA3, the controller 220 may select the gain switching range 1 in FIG. 1 as the first gain switching range. The power amplifier PA200 has more time than other gain switching ranges to amplify the up signal in the high gain mode. In other embodiments, the controller 220 can determine the first gain switching range based on the distribution of PA+ parameters. The smaller the distribution range of the PA+ parameters, the more time the first gain switching range determined by the controller 220 will be in the lower gain mode. The larger the distribution range of PA+ parameters, the more time the first gain switching range determined by controller 220 will be in the higher gain mode. under.
回到第3圖,控制器220接著判斷剛決定的第一增益切換範圍是否和上次的第一增益切換範圍不同(S305)。如果相同,則切換方法3回到步驟302重新計算PA參數。如果不同,切換方法3可繼續評估此PA增益模式範圍是否影響目前的RF效能(S306)。控制器220能計算放大後上行訊號的相鄰頻道功率泄漏比(相鄰通道Leakage功率Rate,以下稱為ACLR)、誤差向量振幅值(Error Vector Magnitude,以下稱為EVM)、輸出功率、SNR或QoS參數用以評估目前的RF效能。當使用決定之第一增益切換範圍的RF效能導致通訊連線不穩定或是QoS不符合標準時,控制器220將保留上次的第一增益切換範圍並回到步驟302重新計算PA參數。當使用決定之第一增益切換範圍產生適當的RF效能時,則切換方法3繼續步驟316。步驟306為選擇性步驟。在一些實施例中,切換方法3不需執行步驟306而可直接進行後續步驟316。 Returning to Fig. 3, the controller 220 then determines whether the first gain switching range just determined is different from the previous first gain switching range (S305). If the same, the switching method 3 returns to step 302 to recalculate the PA parameters. If different, the switching method 3 can continue to evaluate whether the PA gain mode range affects the current RF performance (S306). The controller 220 can calculate the adjacent channel power leakage ratio of the amplified uplink signal (adjacent channel Leakage power Rate, hereinafter referred to as ACLR), error vector magnitude (hereinafter referred to as EVM), output power, SNR or The QoS parameters are used to evaluate current RF performance. When the RF performance of the determined first gain switching range is used to cause the communication connection to be unstable or the QoS does not meet the criteria, the controller 220 will retain the last first gain switching range and return to step 302 to recalculate the PA parameters. When the determined first gain switching range is used to generate the appropriate RF performance, then the switching method 3 continues with step 316. Step 306 is an optional step. In some embodiments, the switching method 3 does not need to perform step 306 but can proceed directly to the subsequent step 316.
對外部資訊功能來說,控制器220能檢查外部資訊功能選項是否已經啟動(S308)。如果尚未啟動,則控制器220持續或定時繼續檢查外部資訊功能選項的狀態(S308)。 For the external information function, the controller 220 can check whether the external information function option has been activated (S308). If not yet activated, the controller 220 continues to check the status of the external information function option continuously or periodically (S308).
如果已經啟動控制器220便能根據外部資訊產生上行訊號,進而決定代表上行訊號輸出功率分布的一種PA參數(S310)。上述外部資訊可由控制器220、通訊協定模組222和外部資訊模組224產生。例如,通訊協定模組222能接收網路系統端寄送的系統訊息而獲得載波數量、傳送功率和服務品質資訊,外部資訊模組224能根據接收到之下行訊號而計算無 線通道環境的SINR,接著控制器220可根據載波、傳送功率、服務品質資訊、SINR等所有外部資訊而估計而同時產生一或多個數位輸出資料,並將所有產生的數位輸出資料相加以估計第二PA參數。第二PA參數可以是所有數位輸出資料的功率相加值,並且轉為dBm的數值或以數位量化的單位表示。在一段時間之後,控制器220可以獲得代表上行訊號輸出功率分布的第二PA參數分布,如第4圖所示,包括負載1及負載2兩種上行訊號負載以dBm表示,並且PA參數分布直接對應到上行訊號所需功率的分布。每種負載都包括PA-參數範圍、平均值、PA+參數範圍以及前端功率損耗。PA-參數範圍為PA參數的下限值到所有PA參數平均值的範圍,而PA+參數範圍為PA參數的上限值到所有PA參數平均值的範圍。前端功率損耗係上行訊號經過RF電路20,包括RF前端電路202所產生的功率損耗。 If the controller 220 has been activated, an uplink signal can be generated based on the external information, thereby determining a PA parameter representing the output power distribution of the uplink signal (S310). The external information may be generated by the controller 220, the communication protocol module 222, and the external information module 224. For example, the communication protocol module 222 can receive the system information sent by the network system terminal to obtain the carrier quantity, the transmission power, and the service quality information, and the external information module 224 can calculate the received signal according to the downlink signal. The SINR of the line channel environment, and then the controller 220 can estimate one or more digital output data according to all external information such as carrier, transmission power, quality of service information, SINR, etc., and estimate all the generated digital output data. Second PA parameter. The second PA parameter may be the power added value of all digital output data and is converted to a value of dBm or expressed in units of digit quantization. After a period of time, the controller 220 can obtain a second PA parameter distribution representing the output power distribution of the uplink signal. As shown in FIG. 4, the two uplink signal loads including the load 1 and the load 2 are expressed in dBm, and the PA parameter distribution is directly Corresponds to the distribution of power required for the upstream signal. Each load includes the PA-parameter range, average, PA+ parameter range, and front-end power loss. The PA-parameter range is the range from the lower limit of the PA parameter to the average of all PA parameters, while the PA+ parameter range is the range from the upper limit of the PA parameter to the average of all PA parameters. The front end power loss is the upstream signal passing through the RF circuit 20, including the power loss generated by the RF front end circuit 202.
在產生如第4圖所示之PA參數分布表示後,控制器220能根據PA參數的分布而決定第二增益切換範圍(S312)。例如,當第二PA參數的分布如第4圖的負載1時,因為PA參數分布跨越的是小範圍PA2~PA3,控制器220可以選擇第1圖中的增益切換範圍2作為第二增益切換範圍,使功率放大器PA200有比其他增益切換範圍有較多的時間以低增益模式放大上行訊號。當第二PA參數的分布如第4圖的負載2時,因為PA參數分布跨越的是大範圍PA1~PA3,控制器220可以選擇第1圖中的增益切換範圍1作為第一增益切換範圍,使功率放大器PA200有比其他增益切換範圍有較多的時間以 高增益模式放大上行訊號。在其他實施例中,控制器220能根據PA+參數的分布而決定第二增益切換範圍。PA+參數的分布範圍越小,控制器220決定的第二增益切換範圍會有越多時間在較低的增益模式之下。PA+參數的分布範圍越大,控制器220決定的第二增益切換範圍會有越多時間在較高的增益模式之下。 After generating the PA parameter distribution representation as shown in FIG. 4, the controller 220 can determine the second gain switching range based on the distribution of the PA parameters (S312). For example, when the distribution of the second PA parameter is the load 1 of FIG. 4, since the PA parameter distribution spans the small range PA2~PA3, the controller 220 may select the gain switching range 2 in FIG. 1 as the second gain switching. The range allows the power amplifier PA200 to have more time than other gain switching ranges to amplify the up signal in the low gain mode. When the distribution of the second PA parameter is the load 2 of FIG. 4, since the PA parameter distribution spans the wide range PA1~PA3, the controller 220 may select the gain switching range 1 in FIG. 1 as the first gain switching range. Making the power amplifier PA200 have more time than other gain switching ranges The high gain mode amplifies the up signal. In other embodiments, the controller 220 can determine the second gain switching range based on the distribution of the PA+ parameters. The smaller the distribution range of the PA+ parameters, the more time the second gain switching range determined by the controller 220 will be in the lower gain mode. The larger the distribution range of the PA+ parameters, the more time the second gain switching range determined by the controller 220 will be under the higher gain mode.
控制器220接著判斷剛決定的第二增益切換範圍是否和上次的第二增益切換範圍不同(S313)。如果相同,則切換方法3回到步驟310重新計算PA參數。如果不同,切換方法3可繼續評估此PA增益模式範圍是否影響目前的RF效能(S314)。步驟314為選擇性步驟。在一些實施例中,切換方法3不需執行步驟314而可直接進行後續步驟316。控制器220能計算放大後上行訊號的ACLR、EVM、輸出功率、SNR或QoS參數用以評估目前的RF效能。當使用決定之第二增益切換範圍導致降低的RF效能影響通訊的穩定度或是QoS的變動時,控制器220將保留第二增益切換範圍並回到步驟310重新計算PA參數。當使用決定之第二增益切換範圍產生適當的RF效能時,則切換方法3繼續步驟316。 The controller 220 then determines whether the second gain switching range just determined is different from the previous second gain switching range (S313). If the same, the switching method 3 returns to step 310 to recalculate the PA parameters. If different, the switching method 3 can continue to evaluate whether the PA gain mode range affects the current RF performance (S314). Step 314 is an optional step. In some embodiments, the switching method 3 does not need to perform step 314 but can proceed directly to the subsequent step 316. The controller 220 can calculate the ACLR, EVM, output power, SNR or QoS parameters of the amplified uplink signal to evaluate the current RF performance. When the determined second gain switching range results in reduced RF performance affecting communication stability or QoS variation, controller 220 will retain the second gain switching range and return to step 310 to recalculate the PA parameters. When the determined second gain switching range is used to generate the appropriate RF performance, then the switching method 3 continues with step 316.
因為切換方法3可以使用內部資訊功能或外部資訊功能來決定增益切換範圍,所以換產生4種可能的狀況,即內部資訊功能開啟,外部資訊功能關閉;內部資訊功能關閉,外部資訊功能開啟;內部和外部資訊功能皆開啟;以及內部和外部資訊功能皆開啟關閉。當內部和外部資訊功能皆開啟時,可能會產生內部和外部資訊功能產生之增益切換範圍有所衝 突的情形,這時就要使用步驟316-S320來決定要使用的增益切換範圍。因此在步驟316中,控制器220能比較第一和第二增益切換範圍。當兩者相同時,控制器220能使用相同的增益切換範圍和上行訊號的所需功率決定功率放大器PA200的PA增益模式(S324),並且結束切換方法3(S326)。當第一和第二增益切換範圍不同時,控制器220能從第一和第二增益切換範圍中選擇其一作為要使用的增益切換範圍(S318)。在某些實施例中,控制器220能將內部資訊功能或外部資訊功能分別設為第一和第二權限,第一和第二權限具有不同的權限高低,並根據第一和第二權限的權限高低而決定要使用第一或第二增益切換範圍作為要使用增益切換範圍。例如,控制器220能將內部資訊功能設有比外部資訊功能更高的權限,當第一或第二增益切換範圍不同時,控制器220便會使用對應內部資訊功能的第一增益切換範圍作為最後要使用的增益切換範圍。在其他實施例中,控制器220能將PA參數的分布範圍(第一或第二輸出功率範圍大小)中之一較小PA參數的分布範圍(輸出功率範圍大小)對應到之增益切換範圍作為最後要使用的增益切換範圍,使得通訊裝置2的電池壽命得以增加。在另外一些實施例中,控制器220能將PA參數的分布範圍(第一或第二輸出功率範圍大小)中之一較大PA參數的分布範圍(輸出功率範圍大小)對應到之增益切換範圍作為最後要使用的增益切換範圍,使得通訊裝置2的上行訊號品質增加。接著控制器220能使用最後要使用的增益切換範圍和上行訊號的所需功率決定功率放大器PA200的PA增益模式(S324),並且結束切換方 法3(S326)。 Because the switching method 3 can use the internal information function or the external information function to determine the gain switching range, the switch generates four possible conditions, that is, the internal information function is turned on, the external information function is turned off, the internal information function is turned off, and the external information function is turned on; Both the external and external messaging features are turned on; and both internal and external messaging features are turned off. When both internal and external information functions are turned on, there may be a range of gain switching ranges generated by internal and external information functions. In the case of a sudden situation, then steps 316-S320 are used to determine the range of gain switching to be used. Thus in step 316, controller 220 can compare the first and second gain switching ranges. When the two are the same, the controller 220 can determine the PA gain mode of the power amplifier PA200 using the same gain switching range and the required power of the uplink signal (S324), and end the switching method 3 (S326). When the first and second gain switching ranges are different, the controller 220 can select one of the first and second gain switching ranges as the gain switching range to be used (S318). In some embodiments, the controller 220 can set the internal information function or the external information function to the first and second rights respectively, and the first and second rights have different permission levels, and according to the first and second rights The privilege level determines whether the first or second gain switching range is to be used as the gain switching range to be used. For example, the controller 220 can set the internal information function to a higher authority than the external information function. When the first or second gain switching range is different, the controller 220 uses the first gain switching range corresponding to the internal information function as The final gain switching range to use. In other embodiments, the controller 220 can correspond to a gain switching range in which a distribution range (output power range size) of one of the distribution parameters (output power range size) of one of the PA parameter distribution ranges (the first or second output power range size) is The final gain switching range to be used allows the battery life of the communication device 2 to be increased. In still other embodiments, the controller 220 can map the distribution range (output power range size) of one of the PA parameter distribution ranges (the first or second output power range size) to the gain switching range. As the last gain switching range to be used, the uplink signal quality of the communication device 2 is increased. Then, the controller 220 can determine the PA gain mode of the power amplifier PA200 using the gain switching range to be used last and the required power of the uplink signal (S324), and end the switching party. Method 3 (S326).
切換方法3在任兩組增益模式間使用多個增益切換範圍,使通訊裝置2可選擇合適增益切換範圍讓功率放大器使用,同時兼顧電池壽命增加以及上行訊號的品質。 The switching method 3 uses multiple gain switching ranges between any two sets of gain modes, so that the communication device 2 can select a suitable gain switching range for the power amplifier to use, taking into account the increase in battery life and the quality of the uplink signal.
第5圖係顯示本發明實施例中另一種功率放大器之增益模式的切換方法5的流程圖,使用第2圖之通訊裝置2。 Fig. 5 is a flow chart showing a method 5 of switching the gain mode of another power amplifier in the embodiment of the present invention, using the communication device 2 of Fig. 2.
在通訊裝置2初始切換方法5後,通訊裝置2能夠依據傳輸資訊而產生上行訊號(S500)。上述傳輸資訊可包括內部資訊或外部資訊。內部資訊可以是上傳速度、頻寬或資料流量限制及其他關於通訊裝置2內部設定的資訊。外部資訊可以是載波數量、傳送功率、服務品質資訊、訊號品質資訊及其他關於通訊裝置2外部環境的資訊。接著,通訊裝置2能經由統計分析一段時間之內的上行訊號輸出功率而決定上行訊號之所需輸出功率的功率範圍大小(S502),並根據功率範圍大小來決定增益切換範圍(S504)。以第4圖和第1圖為例,當所需輸出功率的功率範圍大小是第4圖負載1時,通訊裝置2可選擇第1圖的增益切換範圍2作為增益切換範圍;當所需輸出功率的功率範圍大小是第4圖負載2時,通訊裝置2可選擇第1圖的增益切換範圍1作為增益切換範圍。通訊裝置2能判斷上行訊號之輸出功率是否在增益切換範圍之內,即在所決定之增益切換範圍之上限值和下限值之間。以第1圖為例,當選擇增益切換範圍2時,上行訊號之輸出功率是否在P5和P6間。如果如此,則通訊裝置2能夠使用第一增益模式放大上行訊號(S508)。如果上行訊號之輸出功率超出增益切換範圍之 外,即在第1圖選擇增益切換範圍2的例子中,上行訊號之輸出功率小於P5或大於P6時,則通訊裝置2能夠使用第二增益模式放大上行訊號(S510)。第一增益模式和第二增益模式不同,第一增益模式是切換方法5初始時的預設值或是上次執行切換方法5時最後使用的值。當上行訊號之輸出功率小於P5時,第二增益模式是比第一增益模式低的增益模式,當上行訊號之輸出功率大於P6時,第二增益模式是比第一增益模式高的增益模式。 After the initial switching method 5 of the communication device 2, the communication device 2 can generate an uplink signal according to the transmission information (S500). The above transmission information may include internal information or external information. The internal information can be upload speed, bandwidth or data flow limit and other information about the internal settings of the communication device 2. The external information may be the number of carriers, the transmission power, the quality of service information, the signal quality information, and other information about the external environment of the communication device 2. Next, the communication device 2 can determine the power range size of the required output power of the uplink signal by statistically analyzing the uplink signal output power within a period of time (S502), and determine the gain switching range according to the power range size (S504). Taking FIG. 4 and FIG. 1 as an example, when the power range of the required output power is the load 1 of FIG. 4, the communication device 2 can select the gain switching range 2 of FIG. 1 as the gain switching range; when the desired output is required When the power range of the power is the load 2 of FIG. 4, the communication device 2 can select the gain switching range 1 of FIG. 1 as the gain switching range. The communication device 2 can determine whether the output power of the uplink signal is within the gain switching range, that is, between the upper limit value and the lower limit value of the determined gain switching range. Taking Fig. 1 as an example, when the gain switching range 2 is selected, whether the output power of the uplink signal is between P5 and P6. If so, the communication device 2 can amplify the up signal using the first gain mode (S508). If the output power of the uplink signal exceeds the gain switching range Further, in the example in which the gain switching range 2 is selected in FIG. 1, when the output power of the uplink signal is less than P5 or greater than P6, the communication device 2 can amplify the uplink signal using the second gain mode (S510). The first gain mode is different from the second gain mode, which is the preset value at the initial time of the switching method 5 or the last used value when the switching method 5 was last executed. When the output power of the uplink signal is less than P5, the second gain mode is a lower gain mode than the first gain mode. When the output power of the uplink signal is greater than P6, the second gain mode is a gain mode higher than the first gain mode.
切換方法5在任兩組增益模式間使用多個增益切換範圍,使通訊裝置2可選擇合適增益切換範圍讓功率放大器使用,同時兼顧電池壽命增加以及上行訊號的品質。 The switching method 5 uses a plurality of gain switching ranges between any two sets of gain modes, so that the communication device 2 can select a suitable gain switching range for the power amplifier to use, taking into account the increase in battery life and the quality of the uplink signal.
第6圖係顯示本發明實施例中一種異構(heterogeneous)網路6的示意圖,包括無線區域網路(Wireless Local Area Network,WLAN)60和無線個人網絡(Wireless Personal Area Network,WPAN)62。無線裝置64(行動裝置)可在網路60和62之間漫遊並分別以射頻訊號SWLAN或SWPAN與網路60或62溝通。 FIG. 6 is a schematic diagram showing a heterogeneous network 6 in the embodiment of the present invention, including a Wireless Local Area Network (WLAN) 60 and a Wireless Personal Area Network (WPAN) 62. Wireless device 64 (mobile device) can roam between networks 60 and 62 and communicate with network 60 or 62 with radio frequency signals SWLAN or SWPAN, respectively.
異構網路6可以是一種包括WLAN60和WPLAN62之軟體定義網路。WLAN60覆蓋本地範圍例如住家、學校、實驗室、辦公室大樓或零售店,而WPLAN62覆蓋裝置間之資料傳送,例如電腦、電話、和配備無線通訊能力之個人電子裝置。由於WLAN60和WPLAN62之無線覆蓋範圍的範圍大為不同,無線裝置64可使用不同傳送功率範圍與WLAN60和WPLAN62溝通。因此無線裝置64可根據傳送功率控制資訊動態以及主 動採用增益切換點或增益切換範圍以產生輸出訊號SWLAN或SWPAN。傳送功率控制資訊可為連線網路之無線覆蓋範圍或連線網路之最大允許傳送功率。另外傳送功率控制資訊可包括,但不受限於無線資源管理(Radio Resource Management,RRM),傳送功率控制(Transmit Power Control,TPC)、服務品質(Quality of Service,QoS)或無線通訊網路之網路種類。 The heterogeneous network 6 can be a software-defined network including WLAN 60 and WPLAN 62. WLAN 60 covers local areas such as homes, schools, laboratories, office buildings or retail stores, while WPLAN 62 covers data transfer between devices, such as computers, telephones, and personal electronic devices with wireless communication capabilities. Since the range of wireless coverage of WLAN 60 and WPLAN 62 is quite different, wireless device 64 can communicate with WLAN 60 and WPLAN 62 using different transmit power ranges. Therefore, the wireless device 64 can control the information dynamics according to the transmission power and the main A gain switching point or a gain switching range is used to generate an output signal SWLAN or SWPAN. The transmit power control information can be the wireless coverage of the connected network or the maximum allowed transmit power of the connected network. In addition, the transmission power control information may include, but is not limited to, Radio Resource Management (RRM), Transmit Power Control (TPC), Quality of Service (QoS), or a network of wireless communication networks. Type of road.
例如當無線裝置64移入WLAN60並與WLAN60建立無線連線時,無線裝置64可根據WLAN60的網路種類辨識無線覆蓋範圍,根據WLAN60之網路種類的無線覆蓋範圍決定高增益切換範圍,並使用高增益切換範圍決定之功率增益產生輸出訊號SWLAN;當無線裝置64從WLAN60切換至WPAN62時,無線裝置64可與WPAN62建立另一條無線連線,根據WPAN62之網路種類辨識無線覆蓋範圍,根據WPAN62之網路種類的的無線覆蓋範圍決定低增益切換範圍,並使用低增益切換範圍所決定之功率增益產生輸出訊號SWPAN。因為WLAN60相較於WPAN62具有較大無線覆蓋範圍,而高增益切換範圍相較於低增益切換範圍可覆蓋較低功率範圍,所以無線裝置64可藉由使用高增益切換範圍相較於低增益切換範圍提早切換至較高增益。第7圖顯示不同增益切換範圍的詳細運作方式。藉由根據不同網路種類的無線覆蓋範圍選擇增益切換範圍,無線裝置64在具有較小無線覆蓋範圍之通訊網路中可使用較小傳送功率來傳送RF訊號,並且在具有較大無線覆蓋範圍之通訊網路中可使用較大傳送功率來傳送RF訊號,藉以減低功率消耗並延長電池壽命,同時提供充足的傳送功率用以在 通訊網路中傳送RF訊號。 For example, when the wireless device 64 moves into the WLAN 60 and establishes a wireless connection with the WLAN 60, the wireless device 64 can identify the wireless coverage according to the network type of the WLAN 60, and determine the high gain switching range according to the wireless coverage of the network type of the WLAN 60, and use the high The power gain determined by the gain switching range produces an output signal SWLAN; when the wireless device 64 switches from the WLAN 60 to the WPAN 62, the wireless device 64 can establish another wireless connection with the WPAN 62, and identify the wireless coverage according to the network type of the WPAN 62, according to the WPAN 62 The wireless coverage of the network type determines the low gain switching range and produces the output signal SWPAN using the power gain determined by the low gain switching range. Because WLAN 60 has a larger wireless coverage than WPAN 62, and the high gain switching range can cover a lower power range than the low gain switching range, wireless device 64 can switch by using a high gain switching range compared to low gain. The range switches early to a higher gain. Figure 7 shows the detailed operation of the different gain switching ranges. By selecting the gain switching range according to the wireless coverage of different network types, the wireless device 64 can transmit the RF signal using a smaller transmission power in a communication network having a smaller wireless coverage, and has a larger wireless coverage. Larger transmit power can be used in the communication network to transmit RF signals, thereby reducing power consumption and extending battery life while providing sufficient transmit power for The RF signal is transmitted in the communication network.
於其他例子中,無線裝置64可根據最大允許傳送功率決定增益切換範圍。在無線裝置64與無線通訊網路例如WLAN60建立無線連線後,無線裝置64可從無線通訊網路接收最大允許傳送功率,例如傳送功率控制(Transmit Power Control,TPC)指令。WLAN60分派最大允許傳送功率給無線裝置64以避免不同無線通訊網路或不同無線裝置間之存在太多不想要的訊號干擾。因此無線裝置64可根據最大允許傳送功率決定增益切換範圍。特別是,當最大允許傳送功率較大時,無線裝置64可使用高增益切換範圍控制WLAN訊號SWLAN之功率增益;當最大允許傳送功率較低時,無線裝置64可使用低增益切換範圍控制WLAN訊號SWLAN之功率增益。依照上述內容,相較於低增益切換範圍高增益切換範圍可覆蓋較低功率範圍。因此當最大允許傳送功率較大時,相較於使用低增益切換範圍無線裝置64可使用高增益切換範圍提早切換至較高增益以提供較大傳送功率給WLAN訊號SWLAN。反之當最大允許傳送功率較低時,相較於使用高增益切換範圍無線裝置64可使用低增益切換範圍較慢切換至較高增益以提供較低傳送功率給WLAN訊號SWLAN。不同增益切換範圍的運作細節請參考第7圖。藉由根據最大允許傳送功率選擇增益切換範圍,無線裝置64可針對較小最大允許傳送功率使用較小傳送功率傳送RF訊號,並且針對較大最大允許傳送功率使用較大傳送功率傳送RF訊號,藉以減低功率消耗並延長電池壽命,同時提供充足的傳送功率來達到最大允許傳送功率。 In other examples, wireless device 64 may determine a gain switching range based on the maximum allowed transmit power. After the wireless device 64 establishes a wireless connection with a wireless communication network, such as WLAN 60, the wireless device 64 can receive the maximum allowed transmit power, such as a Transmit Power Control (TPC) command, from the wireless communication network. The WLAN 60 dispatches the maximum allowed transmit power to the wireless device 64 to avoid excessive unwanted signal interference between different wireless communication networks or different wireless devices. The wireless device 64 can therefore determine the gain switching range based on the maximum allowed transmit power. In particular, when the maximum allowed transmission power is large, the wireless device 64 can control the power gain of the WLAN signal SWLAN using the high gain switching range; when the maximum allowed transmission power is low, the wireless device 64 can control the WLAN signal using the low gain switching range. Power gain of the SWLAN. In accordance with the above, the high gain switching range can cover the lower power range compared to the low gain switching range. Therefore, when the maximum allowed transmission power is large, the wireless device 64 can use the high gain switching range to switch to the higher gain early to provide a larger transmission power to the WLAN signal SWLAN than the low gain switching range. Conversely, when the maximum allowed transmission power is low, the wireless device 64 can switch to a higher gain using a lower gain switching range than the high gain switching range to provide lower transmission power to the WLAN signal SWLAN. Please refer to Figure 7 for details of the operation of different gain switching ranges. By selecting the gain switching range based on the maximum allowed transmit power, the wireless device 64 can transmit the RF signal with a smaller transmit power for the smaller maximum allowed transmit power and the RF signal with a larger transmit power for the larger maximum allowable transmit power. Reduce power consumption and extend battery life while providing sufficient transmit power to achieve maximum allowable transmit power.
簡言之,無線裝置64根據傳送功率控制資訊適應性改變增益切換範圍藉以產生傳送到異構網路6之RF訊號,進而減低功率消耗並延長電池壽命,同時提供充足的傳送功率以達到異構網路6之功率需求。 In short, the wireless device 64 adaptively changes the gain switching range according to the transmission power control information to generate an RF signal transmitted to the heterogeneous network 6, thereby reducing power consumption and extending battery life while providing sufficient transmission power to achieve heterogeneity. The power requirements of the network 6.
第6圖係顯示本發明實施例中功率放大器之功率增益和所需傳送功率關係的示意圖,包括高增益切換範圍SW1、中增益切換範圍SW2、和低增益切換範圍SW3,每個增益切換範圍包括3個增益模式,即增益G1、G2、和G3。因此第6圖之無線裝置64可從高增益切換範圍SW1、中增益切換範圍SW2、和低增益切換範圍SW3中選擇一個增益切換範圍。 6 is a schematic diagram showing the relationship between the power gain of the power amplifier and the required transmission power in the embodiment of the present invention, including a high gain switching range SW1, a medium gain switching range SW2, and a low gain switching range SW3, each of which includes Three gain modes, namely gains G1, G2, and G3. Therefore, the wireless device 64 of FIG. 6 can select one of the gain switching ranges from the high gain switching range SW1, the medium gain switching range SW2, and the low gain switching range SW3.
當選擇高增益切換範圍SW1時,且當傳送功率小於5dBm時無線裝置64可使用增益G1產生RF訊號,當傳送功率介於5到12dBm之間時無線裝置64可使用增益G2產生RF訊號,當傳送功率超出12dBm時無線裝置64可使用增益G3產生RF訊號。當選擇中增益切換範圍SW2時,且當傳送功率小於6dBm時無線裝置64可使用增益G1產生RF訊號,當傳送功率介於6到13dBm之間時無線裝置64可使用增益G2產生RF訊號,當傳送功率超出13dBm時無線裝置64可使用增益G3產生RF訊號。當選擇低增益切換範圍SW3時,且當傳送功率小於7dBm時無線裝置64可使用增益G1產生RF訊號,當傳送功率介於7到14dBm之間時無線裝置64可使用增益G2產生RF訊號,當傳送功率超出14dBm時無線裝置64可使用增益G3產生RF訊號。 When the high gain switching range SW1 is selected, and when the transmission power is less than 5 dBm, the wireless device 64 can generate the RF signal using the gain G1, and the wireless device 64 can use the gain G2 to generate the RF signal when the transmission power is between 5 and 12 dBm. The wireless device 64 can generate the RF signal using the gain G3 when the transmission power exceeds 12 dBm. When the medium gain switching range SW2 is selected, and when the transmission power is less than 6 dBm, the wireless device 64 can generate the RF signal using the gain G1, and the wireless device 64 can use the gain G2 to generate the RF signal when the transmission power is between 6 and 13 dBm. The wireless device 64 can generate the RF signal using the gain G3 when the transmission power exceeds 13 dBm. When the low gain switching range SW3 is selected, and when the transmission power is less than 7 dBm, the wireless device 64 can generate the RF signal using the gain G1, and the wireless device 64 can use the gain G2 to generate the RF signal when the transmission power is between 7 and 14 dBm. The wireless device 64 can generate the RF signal using the gain G3 when the transmission power exceeds 14 dBm.
由第7圖可看到相較於中增益切換範圍SW2和低 增益切換範圍SW3,高增益切換範圍SW1較早切換到較高增益,因此若採用高增益切換範圍SW1而不是採用中增益切換範圍SW2和低增益切換範圍SW3,無線裝置64會消耗較多功率來傳送RF訊號。例如當無線裝置64需要13.5dBm傳送功率(Tx功率)以傳送RF訊號時,若採用低增益切換範圍SW3無線裝置64會選擇增益G2來產生RF訊號,以及若採用中增益切換範圍SW2或高增益切換範圍SW1則無線裝置64會選擇增益G3d。在某些實施例中,不同增益由不同數量的放大器或電晶體實現,且通常較高增益由較多數量的放大器或電晶體實現,例如增益G1以1個放大器實現,增益G2以2個放大器實現,且增益G3以3個放大器實現。較高增益由啟動更多數量的放大器或電晶體提供,因此在本發明實施例中當採用中增益切換範圍SW2或高增益切換範圍SW1時,無線裝置64會消耗更大量的功率來產生RF訊號。 It can be seen from Figure 7 that compared to the medium gain switching range SW2 and low The gain switching range SW3, the high gain switching range SW1 switches to a higher gain earlier, so if the high gain switching range SW1 is used instead of the medium gain switching range SW2 and the low gain switching range SW3, the wireless device 64 consumes more power. Send RF signals. For example, when the wireless device 64 needs 13.5 dBm transmission power (Tx power) to transmit the RF signal, if the low gain switching range SW3 is used, the wireless device 64 selects the gain G2 to generate the RF signal, and if the medium gain switching range SW2 or high gain is employed. In the switching range SW1, the wireless device 64 selects the gain G3d. In some embodiments, different gains are achieved by different numbers of amplifiers or transistors, and typically higher gains are achieved by a larger number of amplifiers or transistors, such as gain G1 implemented with 1 amplifier and gain G2 with 2 amplifiers. This is achieved, and the gain G3 is implemented with 3 amplifiers. The higher gain is provided by starting a larger number of amplifiers or transistors, so in the embodiment of the invention, when the medium gain switching range SW2 or the high gain switching range SW1 is employed, the wireless device 64 consumes a larger amount of power to generate the RF signal. .
第8圖係顯示本發明實施例中一種行動裝置8的區塊圖,包括數位類比轉換器(DAC)80、加法器81、混頻器82、程控增益放大器(Programmable Gain Amplifier,PGA)83、濾波器和天線切換器84、控制電路85、本地震盪器(LO)86、頻率合成器87、天線88a和88b以及記憶體裝置89。行動裝置8可作為第6圖之無線裝置64。 8 is a block diagram showing a mobile device 8 in an embodiment of the present invention, including a digital analog converter (DAC) 80, an adder 81, a mixer 82, and a Programmable Gain Amplifier (PGA) 83. Filter and antenna switch 84, control circuit 85, present oscillator (LO) 86, frequency synthesizer 87, antennas 88a and 88b, and memory device 89. The mobile device 8 can be used as the wireless device 64 of FIG.
行動裝置8可通過二或更多個連續通訊通道傳送二或更多個RF訊號至通訊網路。該二或更多個連續通道之頻率互相連續,使共同PGA83可從DAC80中電路A800、電路B802、以及其他電路(未圖式)放大二或更多個類比訊號藉以產 生二或更多個頻率-相鄰的RF訊號用於訊號傳送。 The mobile device 8 can transmit two or more RF signals to the communication network through two or more consecutive communication channels. The frequencies of the two or more consecutive channels are continuous with each other, so that the common PGA 83 can be amplified by two or more analog signals from circuit A800, circuit B802, and other circuits (not shown) in DAC 80. Two or more frequencies - adjacent RF signals are used for signal transmission.
由於二或更多個RF訊號由共同PGA83放大,且每個RF訊號可對應特定外部資訊(傳送功率控制資訊)和/或特定內部資訊,行動裝置8可對二或更多個RF訊號根據外部資訊和/或內部資訊來動態決定放大器增益切換範圍,並使用增益切換範圍決定增益,藉以產生並通過二或更多個連續通道傳送二或更多個RF訊號至通訊網路。 Since two or more RF signals are amplified by the common PGA 83, and each RF signal can correspond to specific external information (transmission power control information) and/or specific internal information, the mobile device 8 can perform two or more RF signals according to the external Information and/or internal information to dynamically determine the amplifier gain switching range and use the gain switching range to determine the gain to generate and transmit two or more RF signals to the communication network over two or more consecutive channels.
無線通訊網路會傳送外部資訊,且外部資訊可包括但不受限於無線資源管理(Radio Resource Management,RRM)、傳送功率控制(Transmit Power Control,TPC)、服務品質(Quality of Service,QoS)或無線通訊網路之網路種類。內部資訊可包括但不受限於依附狀態、應用程式屬性、傳送資料的傳送行為、使用者行為傳送資料以及運作模式例如傳送資料模式、控制資料模式、啟動模式、待機模式、平日模式、假期模式、省電模式、效能導向模式、以及平衡模式。依附狀態可以是行動裝置8的依附狀態或分離狀態,表示行動裝置8在待機模式下被掛上或在啟動模式下被拿起。應用程式屬性可為資料率或應用程式的服務種類。傳送資料的傳送行為可為資料種類的資料率,例如傳送資料和控制資料。使用者行為可包括行動裝置8之用戶在不同期間,例如平日、週末、假期、白天或晚上使用的應用程式或通訊網路。 The wireless communication network transmits external information, and the external information may include, but is not limited to, Radio Resource Management (RRM), Transmit Power Control (TPC), Quality of Service (QoS), or The type of network for wireless communication networks. Internal information may include, but is not limited to, attachment status, application attributes, transfer behavior of transmitted data, user behavior transfer data, and operational modes such as transfer data mode, control data mode, startup mode, standby mode, weekday mode, holiday mode , power saving mode, performance guiding mode, and balancing mode. The attachment state may be an attached state or a separated state of the mobile device 8, indicating that the mobile device 8 is hung in the standby mode or picked up in the startup mode. The application properties can be the data rate or the type of service the application is. The transmission behavior of the transmitted data may be the data rate of the data type, such as the transmission data and the control data. User behavior may include an application or communication network used by a user of the mobile device 8 during different periods, such as weekdays, weekends, holidays, day or night.
DAC80包括電路A800、電路B802、以及其他電路(未圖式),並從基頻電路(未圖式)接收用於不同應用程式或資料種類之基頻資料藉以於相鄰頻帶上輸出二或更多個類比 訊號。實作上電路A800和電路B802將用於不同應用程式或不同資料種類之資料轉換至類比訊號。 The DAC 80 includes circuit A800, circuit B802, and other circuits (not shown), and receives baseband data for different applications or data types from a baseband circuit (not shown) to output two or more frequencies in adjacent frequency bands. Multiple analogies Signal. In practice, circuit A800 and circuit B802 convert data for different applications or different data types to analog signals.
加法器81結合二或更多個類比訊號藉以輸出結合訊號,該結合訊號具有不同頻帶上之二或更多個類比訊號,接著混頻器82藉由頻率合成器87所產生之中央載波頻率上轉換結合訊號,頻率合成器87藉由LO86輸出之震盪訊號產生中央載波頻率。PGA83使用控制電路85之增益訊號SG選擇之增益放大上轉換訊號。 The adder 81 combines two or more analog signals to output a combined signal having two or more analog signals in different frequency bands, and then the mixer 82 is generated on the central carrier frequency generated by the frequency synthesizer 87. Converting the combined signal, the frequency synthesizer 87 generates the center carrier frequency by the oscillating signal output by the LO86. The PGA 83 uses the gain selected by the gain signal SG of the control circuit 85 to amplify the up-converted signal.
控制電路85包括控制器850、內部資訊電路852、和外部資訊電路854,且可根據儲存於記憶體裝置89之外部資訊890和內部資訊892決定PGA83之放大器增益。 The control circuit 85 includes a controller 850, an internal information circuit 852, and an external information circuit 854, and can determine the amplifier gain of the PGA 83 based on the external information 890 and the internal information 892 stored in the memory device 89.
內部資訊電路852可根據行動裝置之內部資訊892決定PGA83之輸出功率範圍。內部資訊892可包括但不受限於傳送資料之傳送行為、依附狀態、應用程式屬性、使用者行為、傳送資料模式、以及運作模式例如控制資料模式、啟動(active)模式、待機(inactive)模式、平日模式、假期模式、省電模式、效能導向模式、以及平衡模式。 The internal information circuit 852 can determine the output power range of the PGA 83 based on the internal information 892 of the mobile device. The internal information 892 may include, but is not limited to, transfer behavior of the transfer data, attachment status, application attributes, user behavior, transfer data mode, and operational modes such as control data mode, active mode, and inactive mode. , weekday mode, holiday mode, power saving mode, performance oriented mode, and balanced mode.
在一個實施例中,內部資訊892可為傳送資料之傳送行為,其中傳送資料可以是傳送資料或控制資料,且傳送資料之傳送行為可包括高吞吐量,而控制資料之傳送行為可包括低吞吐量。在一個例子中,行動裝置8可藉由電路A800產生傳送資料A並藉由電路B802產生傳送資料B,且內部資訊電路852可決定行動裝置之內部資訊892為效能導向模式,並根據效能導向模式決定PGA83之輸出功率範圍。效能導向模 式係為一種功率模式,其中PGA83需要大傳送功率來產生RF訊號。在另一個例子中,行動裝置8可透過電路A800產生傳送資料A並透過電路B802產生控制資料B,並且內部資訊電路852可決定行動裝置之內部資訊892為平衡模式,並根據平衡模式決定PGA83之輸出功率範圍。平衡模式係為一種功率模式,其中PGA83需要中等傳送功率來產生RF訊號。在另一個例子中,行動裝置8可藉由電路A800產生控制資料A並可藉由電路B802傳送資料B,且內部資訊電路852可決定行動裝置之內部資訊892為平衡模式,並根據平衡模式決定PGA83之輸出功率範圍。在另一個例子中行動裝置8可藉由電路A產生控制資料A800以及藉由電路B802產生控制資料B,且內部資訊電路852可決定行動裝置之內部資訊892為省電模式,並根據省電模式決定PGA83之輸出功率範圍。省電模式係為一種功率模式,其中PGA83需要小傳送功率來產生RF訊號。 In one embodiment, the internal information 892 may be a transmission behavior of the transmission data, wherein the transmission data may be a transmission data or a control data, and the transmission behavior of the transmission data may include high throughput, and the transmission behavior of the control data may include low throughput. the amount. In one example, the mobile device 8 can generate the transmission data A by the circuit A800 and the transmission data B by the circuit B802, and the internal information circuit 852 can determine the internal information 892 of the mobile device as the performance-oriented mode, and according to the performance-oriented mode. Determine the output power range of the PGA83. Performance-oriented mode The system is a power mode in which the PGA 83 requires large transmit power to generate RF signals. In another example, the mobile device 8 can generate the transmission data A through the circuit A800 and the control data B through the circuit B802, and the internal information circuit 852 can determine the internal information 892 of the mobile device in a balanced mode, and determine the PGA83 according to the balance mode. Output power range. The balanced mode is a power mode in which the PGA 83 requires medium transmit power to generate RF signals. In another example, the mobile device 8 can generate the control data A through the circuit A800 and can transmit the data B through the circuit B802, and the internal information circuit 852 can determine that the internal information 892 of the mobile device is in a balanced mode, and is determined according to the balance mode. The output power range of the PGA83. In another example, the mobile device 8 can generate the control data A800 by the circuit A and the control data B by the circuit B802, and the internal information circuit 852 can determine that the internal information 892 of the mobile device is the power saving mode, and according to the power saving mode. Determine the output power range of the PGA83. The power saving mode is a power mode in which the PGA 83 requires a small transmission power to generate an RF signal.
當內部資訊電路852決定內部資訊892為效能導向模式時會需要大傳送功率,因此控制器850可決定高增益切換範圍為PGA83之放大器增益切換範圍。當內部資訊電路852決定內部資訊892為省電模式時會需要小傳送功率,因此控制器850可決定低增益切換範圍為PGA83之放大器增益切換範圍。當內部資訊電路852決定內部資訊892為平衡模式時會需要中等傳送功率,因此控制器850可決定中增益切換範圍為PGA83之放大器增益切換範圍。高增益切換範圍、中增益切換範圍、和低增益切換範圍可分別為第7圖中之高增益切換範圍SW1、中增益切換範圍SW2、和低增益切換範圍SW3。低增益 切換範圍包括第一上界和第一下界,中增益切換範圍包括第二上界和第二下界,且高增益切換範圍包括第三上界和第三下界。第三上界小於第二上界,第二上界小於第一上界;以及第三下界小於第二下界,且第二下界小於第一下界。 When the internal information circuit 852 determines that the internal information 892 is in the performance steering mode, a large transmission power is required, so the controller 850 can determine the high gain switching range to the amplifier gain switching range of the PGA 83. When the internal information circuit 852 determines that the internal information 892 is in the power saving mode, a small transmission power is required, so the controller 850 can determine the low gain switching range to the amplifier gain switching range of the PGA 83. The medium transmit power is required when the internal information circuit 852 determines that the internal information 892 is in the balanced mode, so the controller 850 can determine the mid-gain switching range to the amplifier gain switching range of the PGA 83. The high gain switching range, the medium gain switching range, and the low gain switching range may be the high gain switching range SW1, the medium gain switching range SW2, and the low gain switching range SW3 in FIG. 7, respectively. Low gain The switching range includes a first upper bound and a first lower bound, the middle gain switching range includes a second upper bound and a second lower bound, and the high gain switching range includes a third upper bound and a third lower bound. The third upper bound is smaller than the second upper bound, the second upper bound is smaller than the first upper bound; and the third lower bound is smaller than the second lower bound, and the second lower bound is smaller than the first lower bound.
控制器850可接著選擇一增益模式,用於設定PGA83之增益。例如當RF訊號之所需傳送功率在放大器增益切換範圍之內時,控制器850可選擇第一增益模式作為PGA83之增益;以及當RF訊號之所需傳送功率在放大器增益切換範圍之外時,選擇第二增益模式作為PGA83之增益。請參考第7圖,當使用高增益切換範圍SW1且所需傳送功率為8dBm時,控制器850可決定所需傳送功率在高增益切換範圍SW1之內並選擇增益G2作為PGA83之增益;而當所需傳送功率為13.5dBm時,控制器850可決定所需傳送功率在高增益切換範圍SW1之外,並選擇增益G3作為PGA83之增益。控制器850可設定PGA83之增益透過增益訊號SG。 Controller 850 can then select a gain mode for setting the gain of PGA 83. For example, when the required transmit power of the RF signal is within the amplifier gain switching range, the controller 850 can select the first gain mode as the gain of the PGA 83; and when the required transmit power of the RF signal is outside the amplifier gain switching range, The second gain mode is selected as the gain of the PGA 83. Referring to FIG. 7, when the high gain switching range SW1 is used and the required transmission power is 8 dBm, the controller 850 can determine the required transmission power within the high gain switching range SW1 and select the gain G2 as the gain of the PGA 83; When the required transmission power is 13.5 dBm, the controller 850 can determine that the required transmission power is outside the high gain switching range SW1 and select the gain G3 as the gain of the PGA 83. The controller 850 can set the gain of the PGA 83 to pass through the gain signal SG.
接著請參考第8圖,在PGA83使用所選擇之放大器增益產生RF訊號後,濾波器和天線切換器84可從複數組天線88a到88b中選擇二或更多個天線並透過所選擇之天線傳送RF訊號。 Next, referring to FIG. 8, after the PGA 83 generates the RF signal using the selected amplifier gain, the filter and antenna switch 84 can select two or more antennas from the complex array antennas 88a to 88b and transmit them through the selected antenna. RF signal.
在某些實施例中,外部資訊電路852可根據外部資訊892(傳送功率控制資訊)決定PGA83之輸出功率範圍,且控制器850可根據輸出功率範圍決定放大器增益切換範圍。例如行動裝置8可藉由電路A800產生要傳送至WLAN網路(未圖式)之第一資料並藉由電路B802產生要傳送至WPLN網路 (未圖式)第二資料。外部資訊電路852可從記憶體裝置89內之外部資訊890決定WLAN和WPAN網路之無線覆蓋範圍。由於WLAN覆蓋較大的無線覆蓋範圍且WPAN覆蓋較小的無線覆蓋範圍,外部資訊電路852可針對第一資料決定較大輸出功率範圍並針對第二資料決定較小輸出功率範圍。 In some embodiments, the external information circuit 852 can determine the output power range of the PGA 83 based on the external information 892 (transmission power control information), and the controller 850 can determine the amplifier gain switching range according to the output power range. For example, the mobile device 8 can generate the first data to be transmitted to the WLAN network (not shown) by the circuit A800 and generate the data to be transmitted to the WPLN network through the circuit B802. (not shown) second information. The external information circuit 852 can determine the wireless coverage of the WLAN and WPAN networks from the external information 890 within the memory device 89. Since the WLAN covers a large wireless coverage and the WPAN covers a small wireless coverage, the external information circuit 852 can determine a larger output power range for the first data and a smaller output power range for the second data.
當內部資訊電路852決定第一資料具有較大輸出功率範圍時,控制器850可決定高增益切換範圍作為PGA83之放大器增益切換範圍。當內部資訊電路852決定第二資料具有較小輸出功率範圍時,控制器850可決定低增益切換範圍作為PGA83之放大器增益切換範圍。控制器850接著可根據前述實施例選擇用於設定PGA83增益之增益模式。 When the internal information circuit 852 determines that the first data has a large output power range, the controller 850 can determine the high gain switching range as the amplifier gain switching range of the PGA 83. When the internal information circuit 852 determines that the second data has a smaller output power range, the controller 850 can determine the low gain switching range as the amplifier gain switching range of the PGA 83. Controller 850 can then select a gain mode for setting the gain of PGA 83 in accordance with the foregoing embodiments.
在某些實施例中,內部資訊電路852可根據內部資訊892決定PGA83之輸出功率範圍,並且外部資訊電路852可根據外部資訊890決定PGA83之輸出功率範圍,且控制器850可接著根據內部資訊電路852和外部資訊電路854兩者決定之輸出功率範圍決定PGA83之增益切換範圍,並根據前述實施例選擇設定PGA83之增益的增益模式。大致上當內部資訊電路852和外部資訊電路854之輸出功率範圍所決定之結合輸出功率範圍較窄時,例如小於功率範圍門檻值時,控制器850可設定較低增益切換範圍作為PGA83之放大器增益切換範圍,而當內部資訊電路852和外部資訊電路854之輸出功率範圍所決定之結合輸出功率範圍較寬時,例如超出功率範圍門檻值時,控制器850可設定較高增益切換範圍作為PGA83之放大器增益切換範圍。 In some embodiments, the internal information circuit 852 can determine the output power range of the PGA 83 based on the internal information 892, and the external information circuit 852 can determine the output power range of the PGA 83 based on the external information 890, and the controller 850 can then follow the internal information circuit. The output power range determined by both the 852 and the external information circuit 854 determines the gain switching range of the PGA 83, and the gain mode for setting the gain of the PGA 83 is selected in accordance with the foregoing embodiment. Generally, when the combined output power range determined by the output power range of the internal information circuit 852 and the external information circuit 854 is narrow, for example, less than the power range threshold, the controller 850 can set the lower gain switching range as the amplifier gain switching of the PGA 83. Range, and when the combined output power range determined by the output power range of the internal information circuit 852 and the external information circuit 854 is wide, such as exceeding the power range threshold, the controller 850 can set a higher gain switching range as the amplifier of the PGA 83. Gain switching range.
控制電路85中之內部資訊電路852和/或外部資訊電路854可由儲存在記憶體裝置89的軟體碼實現,並由控制器850載入該軟體碼加以執行,或由硬體電路執行前述段落描述之動作。 The internal information circuit 852 and/or the external information circuit 854 in the control circuit 85 can be implemented by a software code stored in the memory device 89 and loaded by the controller 850 to execute the software code, or the hardware circuit can execute the foregoing paragraph description. The action.
行動裝置8針對二或更多個RF訊號使用外部資訊和/或內部資訊以決定輸出功率範圍,根據輸出功率範圍決定功率放大器之放大器增益切換範圍,並選擇用於功率放大器之增益藉以放大二或更多個RF訊號並通過二或更多個相鄰通訊通道傳送放大的二或更多個RF訊號。行動裝置8之適應性改變放大器增益切換範圍,減低功率消耗並延長電池壽命,同時提供充足的傳送功率以達到針對二或更多個RF訊號之功率需求。 The mobile device 8 uses external information and/or internal information for two or more RF signals to determine an output power range, determines an amplifier gain switching range of the power amplifier according to the output power range, and selects a gain for the power amplifier to amplify the second or More RF signals and two or more amplified RF signals are transmitted through two or more adjacent communication channels. The adaptability of the mobile device 8 changes the amplifier gain switching range, reduces power consumption and extends battery life while providing sufficient transmit power to achieve power requirements for two or more RF signals.
第9圖係顯示本發明實施例中另一種行動裝置9的區塊圖,包括基頻電路90、混頻器91a、91b、PGA92a、92b、濾波器和天線切換器93、天線94a、94b、控制電路95、本地震盪器(Local Oscillator,LO)96、頻率合成器97、和記憶體裝置99。行動裝置8可作為第6圖之無線裝置64。行動裝置9可作為第6圖之無線裝置64。 Figure 9 is a block diagram showing another mobile device 9 in the embodiment of the present invention, including a baseband circuit 90, mixers 91a, 91b, PGA 92a, 92b, a filter and antenna switch 93, antennas 94a, 94b, Control circuit 95, local oscillator (LO) 96, frequency synthesizer 97, and memory device 99. The mobile device 8 can be used as the wireless device 64 of FIG. The mobile device 9 can be used as the wireless device 64 of FIG.
行動裝置8可通過二或更多個非連續通訊通道傳送二或更多個RF訊號至一或更多通訊網路。二或更多個連續通道互相為頻率非連續通道,使PGA92a和92b可各自分別放大來自DAC90中電路A900和電路B902之二或更多個類比訊號,藉以產生二或更多個頻率非連續RF訊號用於訊號傳送。 The mobile device 8 can transmit two or more RF signals to one or more communication networks through two or more non-contiguous communication channels. The two or more consecutive channels are mutually frequency discontinuous channels such that PGAs 92a and 92b can each amplify two or more analog signals from circuit A900 and circuit B902 in DAC 90, respectively, to generate two or more frequency discontinuous RFs. The signal is used for signal transmission.
除了控制電路95和記憶體裝置99可分開並獨立 根據二或更多個RF訊號之外部資訊和/或內部資訊決定PGA92a和92b之放大器增益切換範圍和增益之外,控制電路95和記憶體裝置99的設定以及運作和第8圖之控制電路85和記憶體裝置89完全相同,藉以減低功率消耗並延長電池壽命,同時對二或更多個頻率非連續RF訊號提供充足的傳送功率而達到功率需求。 In addition to the control circuit 95 and the memory device 99 can be separated and independent The setting and operation of the control circuit 95 and the memory device 99 and the control circuit 85 of FIG. 8 are determined in addition to the external gain information and/or internal information of the two or more RF signals to determine the amplifier gain switching range and gain of the PGAs 92a and 92b. It is identical to the memory device 89, thereby reducing power consumption and extending battery life while providing sufficient transmission power for two or more frequency discontinuous RF signals to achieve power requirements.
第10圖係顯示本發明實施例中一種功率控制方法10的流程圖,使用第8圖或第9圖之行動裝置。在開機後或當功率控制應用程式在行動裝置上初始時功率控制方法10可初始化(S1000)。 Figure 10 is a flow chart showing a power control method 10 in an embodiment of the present invention, using the mobile device of Figure 8 or Figure 9. The power control method 10 may be initialized after powering on or when the power control application is initial on the mobile device (S1000).
下一步,功率控制方法10可藉由行動裝置持續並定期監控從無線通訊網路發送的下行訊號,藉以接收輸入RF訊號內之傳送功率控制資訊(S1002)。傳送功率控制資訊可包括但不受限於無線資源管理(Radio Resource Management,RRM)、傳送功率控制(Transmit Power Control,TPC)、服務品質(Quality of Service,QoS)或無線通訊網路之網路種類。 Next, the power control method 10 can continuously and periodically monitor the downlink signal transmitted from the wireless communication network by the mobile device to receive the transmission power control information in the input RF signal (S1002). The transmission power control information may include, but is not limited to, Radio Resource Management (RRM), Transmit Power Control (TPC), Quality of Service (QoS), or network type of the wireless communication network. .
接著功率控制方法10可根據傳送功率控制資訊決定PA的輸出功率範圍(S1004),並決定輸出功率範圍是否小於功率範圍門檻值(S1006)。當輸出功率範圍小於功率範圍門檻值時,功率控制方法10可決定輸出功率範圍很窄並將低增益切換範圍設為行動裝置中功率放大器PA之增益切換範圍(S1010),而當輸出功率範圍超出功率範圍門檻值時,功率控制方法10可決定輸出功率範圍很寬並將高增益切換範圍設為行動裝置中功率放大器PA之增益切換範圍(S1012)。第7圖實 施例包括低增益切換範圍和高增益切換範圍可的定義。 Then, the power control method 10 determines the output power range of the PA according to the transmission power control information (S1004), and determines whether the output power range is smaller than the power range threshold (S1006). When the output power range is less than the power range threshold, the power control method 10 may determine that the output power range is narrow and the low gain switching range is set to the gain switching range of the power amplifier PA in the mobile device (S1010), and when the output power range is exceeded In the power range threshold, the power control method 10 may determine that the output power range is wide and the high gain switching range is set to the gain switching range of the power amplifier PA in the mobile device (S1012). Figure 7 The example includes a definition of a low gain switching range and a high gain switching range.
然後功率控制方法10可根據增益切換範圍決定功率放大器PA之增益,特別是藉由決定上行訊號之所需輸出功率是否在功率放大器PA之增益切換範圍之內(S1012),當所需輸出功率在增益切換範圍之內時,使用第一增益模式放大上行訊號(S1014),並且當所需輸出功率在增益切換範圍之外時,使用第二增益模式放大上行訊號(S1014)。功率控制方法10接著便完成並結束(S1016)。 Then, the power control method 10 can determine the gain of the power amplifier PA according to the gain switching range, in particular, by determining whether the required output power of the uplink signal is within the gain switching range of the power amplifier PA (S1012), when the required output power is When the gain switching range is within, the first gain mode is used to amplify the up signal (S1014), and when the required output power is outside the gain switching range, the second gain mode is used to amplify the up signal (S1014). The power control method 10 is then completed and ends (S1016).
第11圖係顯示本發明實施例中另一種功率控制方法11的流程圖,使用第8圖或第9圖之行動裝置。步驟S1100、和步驟S1106到S1116可和步驟S1000、步驟S1006到S1016完全相同,在前述段落中有詳細解釋在此不另外重述。步驟S1102和S1104以及第10圖步驟S1002和S1004的不同之處在於功率控制方法11可從記憶體裝置接收內部資訊,該從記憶體裝置可為行動裝置內之本地記憶體裝置(S1102),接著根據內部資訊決定功率放大器PA之輸出功率範圍(S1104)。內部資訊可以是但不受限於傳送資料之傳送行為、依附狀態、應用程式屬性、使用者行為、傳送資料模式、和運作模式,例如控制資料模式、啟動模式、待機模式、平日模式、假期模式、省電模式、效能導向模式、和平衡模式。內部資訊在前述段落中有詳細解釋。 Fig. 11 is a flow chart showing another power control method 11 in the embodiment of the present invention, using the mobile device of Fig. 8 or Fig. 9. Step S1100, and steps S1106 to S1116 may be identical to steps S1000, S1006 to S1016, and are not explained in detail herein in the foregoing paragraphs. Steps S1102 and S1104 and step S1002 and S1004 of FIG. 10 are different in that the power control method 11 can receive internal information from the memory device, and the slave memory device can be a local memory device in the mobile device (S1102), and then The output power range of the power amplifier PA is determined based on the internal information (S1104). The internal information may be, but is not limited to, the transmission behavior of the transmission data, the attachment state, the application properties, the user behavior, the transmission data mode, and the operation mode, such as the control data mode, the startup mode, the standby mode, the weekday mode, and the holiday mode. , power saving mode, performance guiding mode, and balancing mode. Internal information is explained in detail in the preceding paragraphs.
功率控制方法10和11可在行動裝置上分開或一起使用以根據傳送功率控制資訊和/或內部資訊適應性改變並動態決定功率放大器之增益切換範圍,並為功率放大器選擇增 益以放大並傳送上行訊號。適應性改變和動態放大器增益切換範圍of功率控制方法10和11減低功率消耗並延長電池壽命,同時提供充足的傳送功率以達到二或更多個RF訊號之功率需求。 The power control methods 10 and 11 can be used separately or together on the mobile device to adaptively change and dynamically determine the gain switching range of the power amplifier based on the transmit power control information and/or internal information, and select for the power amplifier. Benefit to amplify and transmit the upstream signal. Adaptive Change and Dynamic Amplifier Gain Switching Range of Power Control Methods 10 and 11 reduces power consumption and extends battery life while providing sufficient transmit power to achieve power requirements for two or more RF signals.
本申請案對應於美國優先權申請號62/106,948,送件日期為2015年01月23日。其完整內容已整合於此。 This application corresponds to US Priority Application No. 62/106,948, and the delivery date is January 23, 2015. Its full content has been integrated here.
本發明描述之各種邏輯區塊、模組、以及電路可以使用通用處理器、數位訊號處理器(Digital Signal Processor,DSP)、特定應用積體電路(Application Specific Integrated Circuit,ASIC)、或其他可程控邏輯元件、離散式邏輯電路或電晶體邏輯閘、離散式硬體元件、或用於執行本發明所描述之執行的功能之其任意組合。通用處理器可以為微處理器,或者,該處理器可以為任意商用處理器、控制器、微處理器、或狀態機。 The various logic blocks, modules, and circuits described in the present invention may use a general purpose processor, a Digital Signal Processor (DSP), an Application Specific Integrated Circuit (ASIC), or other programmable Any combination of logic elements, discrete logic circuits or transistor logic gates, discrete hardware components, or functions for performing the operations described herein. A general purpose processor may be a microprocessor, or the processor may be any commercially available processor, controller, microprocessor, or state machine.
本發明描述之各種邏輯區塊、模組、以及電路的操作以及功能可以利用電路硬體或嵌入式軟體碼加以實現,該嵌入式軟體碼可以由一處理器存取以及執行。 The operations and functions of the various logic blocks, modules, and circuits described herein can be implemented using circuit hardware or embedded software code that can be accessed and executed by a processor.
雖然本發明已以較佳實施例揭露如上,然其並非用以限定本發明,任何熟習此技藝者,在不脫離本發明之精神和範圍內,當可作各種之更動與潤飾,因此本發明之保護範圍當視後附之申請專利範圍所界定者為準。 While the present invention has been described above by way of a preferred embodiment, it is not intended to limit the invention, and the present invention may be modified and modified without departing from the spirit and scope of the invention. The scope of protection is subject to the definition of the scope of the patent application.
10‧‧‧功率控制方法 10‧‧‧Power control method
S1000、S1002、...、S1016‧‧‧步驟 S1000, S1002, ..., S1016‧‧‧ steps
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