ASUS USB N14 User Manual

¨
USB-N14  
Dual-band Wireless-AC600  
USB Adapter  
User Manual  
Table of contents  
1. Introduction.........................................................................4  
Package contents...........................................................................................4  
System requirements....................................................................................4  
Status indicator...............................................................................................4  
2. Installing the USB-N14 driver.............................................5  
3. Connecting to a wireless network......................................7  
Connecting to a wireless network using WPS .....................................8  
4. Troubleshooting..................................................................9  
5. Glossary..............................................................................10  
Notices .....................................................................................20  
ASUS Contact Information........................................................................24  
1. Introduction  
Package contents  
ASUS USB-N14 adapter x1  
Quick Start Guide x1  
Support CD x1  
Warranty card x1  
USB cable x1  
If any of the above items is damaged or missing, contact your retailer  
immediately.  
System requirements  
Before using the USB-N14 adapter, check if your system meets the following  
requirements:  
Windows® XP / Vista / 7 / 8 / Mac OSX / Linux  
512MB system memory or larger  
USB 2.0 port  
Optical disk drive  
Operating and storage environment  
1. Operating temperature: ambient temperature between 0˚C ~ 40˚C  
2. Storage temperature: ambient temperature between -10˚C ~ 70˚C  
3. Humidity: 5% ~ 90% (non-condensing)  
Status indicator  
LED  
Link  
Status  
On  
Off  
Description  
USB-N14 has connected to a wireless network successfully.  
USB-N14 is not connected.  
Using Wi-Fi Protected Setup (for Windows® OS only)  
To enable Wi-Fi Protected Setup (WPS), press the WPS button on the USB-N14.  
4
2. Installing the USB-N14 driver  
Install the driver from the bundled Support CD before inserting the  
USB-N14 into your computer.  
To install the driver for your ASUS USB-N14:  
1. Place the bundled Support CD in the optical drive. An Autorun screen  
appears if the Autorun function is enabled on your computer.  
If the Autorun function is not enabled on your computer, double-click  
SETUP.EXE from the root directory to run the Support CD.  
2. An InstallShield Wizard screen  
appears. Click Next to continue.  
3. Click Install to install driver to  
default destination folder.  
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4. Click Finish to complete  
installation.  
5. Connect the USB-N14 to the USB  
port on your computer using the  
bundled USB cable.  
Windows will automatically install  
the driver for the device.  
A message will appear in the  
Windows® notification area and the  
LED indicator on USB-N14 turns  
solid blue indicating that device  
drivers have successfully been  
installed.  
6
3. Connecting to a wireless network  
To connect the USB-N14 Wireless adapter to a station or Access Point:  
1. Click the network connection icon  
in the Windows® notification area  
to show the available wireless  
networks list.  
2. Select an Access Point (AP) from  
the list and click Connect.  
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3. If Security is enabled on the AP  
or station, provide the required  
password or passkey. Click OK.  
Connecting to a wireless network using WPS  
The ASUS USB-N14 supports Wi-Fi Protected Setup (WPS) for Windows®  
operating systems for securing wireless connections.  
Ensure that the AP you are trying to connect to supports the WPS  
feature.  
To connect the USB-N14 Wireless adapter to a WPS-enabled AP using the  
WPS button:  
1. Enable the WPS function of the wireless AP.  
2. Press both the WPS buttons on the AP and USB-N14 until the USB-N14  
connects to the wireless AP to establish a secure connection.  
8
4. Troubleshooting  
This chapter provides solutions to problems which you may encounter when  
installing or using ASUS USB-N14. Contact a qualified service technician  
for assistance if the problem still persists after you have performed the  
troubleshooting solutions.  
How do I verify that my WLAN adapter is installed properly?  
1. Right-click My Computer from the Start menu, then select Properties.  
2. Select the Hardware tab, then click Device Manager.  
3. Double-click Network adapters.  
4. Double-click ASUS USB-N14 USB Wireless Adapter. An ASUS  
USB-N14 USB Wireless Adapter window appears.  
5. Check Device status to see if the WLAN adapter is working properly.  
My WLAN adapter cannot connect to any Access Point.  
Check if Network Type is set to Infrastructure mode.  
Check if the SSID of your WLAN adapter is the same as that of the  
Access Point you want to connect to.  
Check if the Encryption settings of your WLAN adapter are the same as  
the Access Point you want to connect to.  
My WLAN adapter cannot connect to a station or WLAN  
adapter.  
Check if Network Type is set to Ad Hoc mode.  
Check if the SSID of your WLAN adapter is the same as that of the  
station or the WLAN adapter you want to connect to.  
Check if the Channel of your WLAN adapter is the same as that of the  
station or the WLAN adapter you want to connect to.  
Check if the Encryption settings of your WLAN adapter are the same as  
those of the station or the WLAN adapter you want to connect to.  
The connection quality is bad and the signal strength is weak.  
Keep your WLAN adapter away from microwave ovens and large metal  
objects to avoid radio interference.  
Move your WLAN adapter closer to the access point, station, or WLAN  
adapter you want to connect to.  
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5. Glossary  
Access Point (AP)  
A networking device that seamlessly connects wired and wireless networks.  
Access Points combined with a distributed system support the creation of  
multiple radio cells that enable roaming throughout a facility.  
Ad Hoc  
A wireless network composed solely of stations within mutual communication  
range of each other (no Access Point).  
Basic Rate Set  
This option allows you to specify the data transmission rate.  
Basic Service Area (BSS)  
A set of stations controlled by a single coordination function.  
Broadband  
A type of data transmission in which a single medium (such as cable) carries  
several data at once.  
Channel  
An instance of medium use for the purpose of passing protocol data units that  
may be used simultaneously, in the same volume of space, with other instances  
of medium use (on other channels) by other instances of the same physical  
layer, with an acceptably low frame error ratio due to mutual interference.  
Client  
A client is the desktop or mobile PC that is connected to your network.  
10  
COFDM (for 802.11a or 802.11g)  
Signal power alone is not enough to maintain 802.11b-like distances in an  
802.11a/g environment. To compensate, a new physical-layer encoding  
technology was designed that departs from the traditional direct-sequence  
technology being deployed today. This technology is called COFDM (coded  
OFDM). COFDM was developed specifically for indoor wireless use and offers  
performance much superior to that of spread-spectrum solutions. COFDM  
works by breaking one high-speed data carrier into several lowerspeed  
subcarriers, which are then transmitted in parallel. Each high-speed carrier is  
20MHz wide and is broken up into 52 subchannels, each approximately 300KHz  
wide. COFDM uses 48 of these subchannels for data, while the remaining four  
are used for error correction. COFDM delivers higher data rates and a high  
degree of multipath reflection recovery, thanks to its encoding scheme and  
error correction.  
Each subchannel in the COFDM implementation is about 300KHz wide. At  
the low end of the speed gradient, BPSK (binary phase shift keying) is used  
to encode 125Kbps of data per channel, resulting in a 6,000Kbps, or 6Mbps,  
data rate. Using quadrature phase shift keying, you can double the amount of  
data encoded to 250Kbps per channel, yielding a 12Mbps data rate. And by  
using 16-level quadrature amplitude modulation encoding 4bits per hertz,  
you can achieve a data rate of 24Mbps. The 802.11a/g standard specifies  
that all 802.11a/g-compliant products must support these basic data rates.  
The standard also lets the vendor extend the modulation scheme beyond  
24Mbps. Remember, the more bits per cycle (hertz) that are encoded, the more  
susceptible the signal will be to interference and fading, and ultimately, the  
shorter the range, unless power output is increased.  
Default Key  
This option allows you to select the default WEP key. This option allows you to  
use WEP keys without having to remember or write them down. The WEP keys  
generated using the Pass Phrase is compatible with other WLAN products. The  
Pass Phrase option is not as secure as manual assignment.  
Device Name  
Also known as DHCP client ID or network name. Sometimes provided by an ISP  
when using DHCP to assign addresses.  
DHCP (Dynamic Host Configuration Protocol)  
This protocol allows a computer (or many computers on your network) to be  
automatically assigned a single IP address from a DHCP server.  
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DNS Server Address (Domain Name System)  
DNS allows Internet host computers to have a domain name and one or  
more IP addresses. A DNS server keeps a database of host computers and  
their respective domain names and IP addresses, so that when a user enters  
a domain name into the Internet browser, the user is sent to the proper IP  
address. The DNS server address used by the computers on your home network  
is the location of the DNS server your ISP has assigned.  
DSL Modem (Digital Subscriber Line)  
A DSL modem uses your existing phone lines to transmit data at high speeds.  
Direct-Sequence Spread Spectrum (for 802.11b)  
Spread spectrum (broadband) uses a narrowband signal to spread the  
transmission over a segment of the radio frequency band or spectrum. Direct-  
sequence is a spread spectrum technique where the transmitted signal is  
spread over a particular frequency range.  
Direct-sequence systems communicate by continuously transmitting a  
redundant pattern of bits called a chipping sequence. Each bit of transmitted  
data is mapped into chips and rearranged into a pseudorandom spreading  
code to form the chipping sequence. The chipping sequence is combined with  
a transmitted data stream to produce the output signal.  
Wireless mobile clients receiving a direct-sequence transmission use the  
spreading code to map the chips within the chipping sequence back into bits  
to recreate the original data transmitted by the wireless device. Intercepting  
and decoding a direct-sequence transmission requires a predefined algorithm  
to associate the spreading code used by the transmitting wireless device to the  
receiving wireless mobile client.  
This algorithm is established by IEEE 802.11b specifications. The bit redundancy  
within the chipping sequence enables the receiving wireless mobile client to  
recreate the original data pattern, even if bits in the chipping sequence are  
corrupted by interference. The ratio of chips per bit is called the spreading ratio.  
A high spreading ratio increases the resistance of the signal to interference. A  
low spreading ratio increases the bandwidth available to the user. The wireless  
device uses a constant chip rate of 11Mchips/s for all data rates, but uses  
different modulation schemes to encode more bits per chip at the higher data  
rates. The wireless device is capable of an 11 Mbps data transmission rate, but  
the coverage area is less than a 1 or 2 Mbps wireless device since coverage area  
decreases as bandwidth increases.  
12  
Encryption  
This provides wireless data transmissions with a level of security. This option  
allows you to specify a 64-bit or a 128-bit WEP key. A 64-bit encryption contains  
10 hexadecimal digits or 5 ASCII characters. A 128-bit encryption contains 26  
hexadecimal digits or 13 ASCII characters.  
64-bit and 40-bit WEP keys use the same encryption method and can  
interoperate on wireless networks. This lower level of WEP encryption uses  
a 40-bit (10 hexadecimal digits assigned by the user) secret key and a 24-bit  
Initialization Vector assigned by the device. 104-bit and 128-bit WEP keys use  
the same encryption method.  
All wireless clients in a network must have identical WEP keys with the access  
point to establish connection. Keep a record of the WEP encryption keys.  
Extended Service Set (ESS)  
A set of one or more interconnected basic service set (BSSs) and integrated  
local area networks (LANs) can be configured as an Extended Service Set.  
ESSID (Extended Service Set Identifier)  
You must have the same ESSID entered into the gateway and each of its  
wireless clients. The ESSID is a unique identifier for your wireless network.  
Ethernet  
The most widely used LAN access method, which is defined by the IEEE 802.3  
standard. Ethernet is normally a shared media LAN meaning all devices on the  
network segment share total bandwidth. Ethernet networks operate at 10Mbps  
using CSMA/CD to run over 10-BaseT cables.  
Firewall  
A firewall determines which information passes in and out of a network. NAT  
can create a natural firewall by hiding a local network’s IP addresses from the  
Internet. A Firewall prevents anyone outside of your network from accessing  
your computer and possibly damaging or viewing your files.  
Gateway  
A network point that manages all the data traffic of your network, as well as to  
the Internet and connects one network to another.  
ICS  
ICS is used to share one computer’s Internet connection with the rest of the  
computers on your network. When this computer is connected to the Internet,  
all the communications to and from the Internet on your network are sent  
through this computer which is called the host computer. The rest of the  
computers can send and receive e-mail messages and access the web as if it  
were connected directly to the Internet.  
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IEEE  
The Institute of Electrical and Electronics Engineers. The IEEE sets standards for  
networking, including Ethernet LANs. IEEE standards ensure interoperability  
between systems of the same type.  
IEEE 802.11  
IEEE 802.xx is a set of specifications for LANs from the Institute of Electrical  
and Electronic Engineers (IEEE). Most wired networks conform to 802.3, the  
specification for CSMA/CD based Ethernet networks or 802.5, the specification  
for token ring networks. 802.11 defines the standard for wireless LANs  
encompassing three incompatible (non-interoperable) technologies: Frequency  
Hopping Spread Spectrum (FHSS), Direct Sequence Spread Spectrum (DSSS),  
and Infrared. 802.11 specifies a carrier sense media access control and physical  
layer specifications for 1 and 2 Mbps wireless LANs.  
IEEE 802.11a (54Mbits/sec)  
Compared with 802.11b: The 802.11b standard was designed to operate in  
the 2.4GHz ISM (Industrial, Scientific and Medical) band using direct-sequence  
spreadspectrum technology. The 802.11a standard, on the other hand, was  
designed to operate in the more recently allocated 5-GHz UNII (Unlicensed  
National Information Infrastructure) band. And unlike 802.11b, the 802.11a  
standard departs from the traditional spread-spectrum technology, instead  
using a frequency division multiplexing scheme that’s intended to be friendlier  
to office environments.  
The 802.11a standard, which supports data rates of up to 54 Mbps, is the Fast  
Ethernet analog to 802.11b, which supports data rates of up to 11 Mbps. Like  
Ethernet and Fast Ethernet, 802.11b and 802.11a use an identical MAC (Media  
Access Control). However, while Fast Ethernet uses the same physical-layer  
encoding scheme as Ethernet (only faster), 802.11a uses an entirely different  
encoding scheme, called OFDM (orthogonal frequency division multiplexing).  
The 802.11b spectrum is plagued by saturation from wireless phones,  
microwave ovens and other emerging wireless technologies, such as Bluetooth.  
In contrast, 802.11a spectrum is relatively free of interference.  
The 802.11a standard gains some of its performance from the higher  
frequencies at which it operates. The laws of information theory tie frequency,  
radiated power and distance together in an inverse relationship. Thus, moving  
up to the 5GHz spectrum from 2.4GHz will lead to shorter distances, given the  
same radiated power and encoding scheme.  
14  
Compared with 802.11g  
802.11a is a standard for access points and radio NICs that is ahead of 802.11g  
in the market by about six months. 802.11a operates in the 5GHz frequency  
band with twelve separate non-overlapping channels. As a result, you can have  
up to twelve access points set to different channels in the same area without  
them interfering with each other. This makes access point channel assignment  
much easier and significantly increases the throughput the wireless LAN can  
deliver within a given area. In addition, RF interference is much less likely  
because of the less-crowded 5GHz band.  
IEEE 802.11b (11Mbits/sec)  
In 1997, the Institute of Electrical and Electronics Engineers (IEEE) adopted the  
802.11 standard for wireless devices operating in the 2.4 GHz frequency band.  
This standard includes provisions for three radio technologies: direct sequence  
spread spectrum, frequency hopping spread spectrum, and infrared. Devices  
that comply with the 802.11 standard operate at a data rate of either 1 or 2  
Mbps.  
In 1999, the IEEE created the 802.11b standard. 802.11b is essentially identical  
to the 802.11 standard except 802.11b provides for data rates of up to 11Mbps  
for direct sequence spread spectrum devices. Under 802.11b, direct sequence  
devices can operate at 11Mbps, 5.5Mbps, 2Mbps, or 1Mbps. This provides  
interoperability with existing 802.11 direct sequence devices that operate only  
at 2Mbps.  
Direct sequence spread spectrum devices spread a radio signal over a range  
of frequencies. The IEEE 802.11b specification allocates the 2.4GHz frequency  
band into 14 overlapping operating Channels. Each Channel corresponds to a  
different set of frequencies.  
IEEE 802.11g  
802.11g is a new extension to 802.11b (used in majority of wireless LANs today)  
that broadens 802.11b’s data rates to 54 Mbps within the 2.4 GHz band using  
OFDM (orthogonal frequency division multiplexing) technology. 802.11g allows  
backward compatibility with 802.11b devices but only at 11 Mbps or lower,  
depending on the range and presence of obstructions.  
Infrastructure  
A wireless network centered about an access point. In this environment, the  
access point not only provides communication with the wired network but also  
mediates wireless network traffic in the immediate neighborhood.  
15  
IP (Internet Protocol)  
The TCP/IP standard protocol that defines the IP datagram as the unit of  
information passed across an Internet and provides the basis for connectionless  
packet delivery service. IP includes the ICMP control and error message  
protocol as an integral part. It provides the functional equivalent of ISO OSI  
Network Services.  
IP Address  
An IP address is a 32-bit number that identifies each sender or receiver of  
information that is sent across the Internet. An IP address has two parts:  
the identifier of a particular network on the Internet and an identifier of the  
particular device (which can be a server or a workstation) within that network.  
ISM Bands (Industrial, Scientific, and Medicine Bands)  
Radio frequency bands that the Federal Communications Commission (FCC)  
authorized for wireless LANs. The ISM bands are located at 902MHz, 2.400GHz,  
and 5.7GHz.  
ISP (Internet Service Provider)  
An organization that provides access to the Internet. Small ISPs provide service  
via modem and ISDN while the larger ones also offer private line hookups (T1,  
fractional T1, etc.).  
LAN (Local Area Network)  
A communications network that serves users within a defined geographical  
area. The benefits include the sharing of Internet access, files and equipment  
like printers and storage devices. Special network cabling (10 Base-T) is often  
used to connect the PCs together.  
MAC Address (Media Access Control)  
A MAC address is the hardware address of a device connected to a network.  
NAT (Network Address Translation)  
NAT masks a local network’s group of IP addresses from the external network,  
allowing a local network of computers to share a single ISP account. This  
process allows all of the computers on your home network to use one IP  
address. This will enable access to the Internet from any computer on your  
home network without having to purchase more IP addresses from your ISP.  
16  
NIC (Network Interface Card)  
A network adapter inserted into a computer so that the computer can be  
connected to a network. It is responsible for converting data from stored in the  
computer to the form transmitted or received.  
Packet  
A basic message unit for communication across a network. A packet usually  
includes routing information, data, and sometimes error detection information.  
Pass Phrase  
The Wireless Settings utility uses an algorithm to generate four WEP keys based  
on the typed combination.  
PCMCIA (Personal Computer Memory Card International  
Association)  
The Personal Computer Memory Card International Association (PCMCIA),  
develops standards for PC cards, formerly known as PCMCIA cards. These  
cards are available in three types, and are about the same length and width as  
credit cards. However, the different width of the cards ranges in thickness from  
3.3 mm (Type I) to 5.0 mm (Type II) to 10.5 mm (Type III). These cards can be  
used for various functions, including memory storage, land line modems and  
wireless modems.  
PPP (Point-to-Point Protocol)  
PPP is a protocol for communication between computers using a serial  
interface, typically a personal computer connected by phone line to a server.  
PPPoE (Point-to-Point Protocol over Ethernet)  
Point-to-Point Protocol is a method of secure data transmission. PPP using  
Ethernet to connect to an ISP.  
Preamble  
Allows you to set the preamble mode for a network to Long, Short, or Auto. The  
default preamble mode is Long.  
Radio Frequency (RF) Terms: GHz, MHz, Hz  
The international unit for measuring frequency is Hertz (Hz), equivalent to the  
older unit of cycles per second. One megahertz (MHz) is one million Hertz.  
One gigahertz (GHz) is one billion Hertz. The standard US electrical power  
frequency is 60Hz, the AM broadcast radio frequency band is 0.55-1.6MHz, the  
FM broadcast radio frequency band is 88-108MHz, and wireless 802.11 LANs  
operate at 2.4GHz.  
17  
SSID (Service Set Identifier)  
SSID is a group name shared by every member of a wireless network. Only  
client PCs with the same SSID are allowed to establish a connection. Enabling  
the Response to Broadcast SSID requests option allows the device to  
broadcast its SSID in a wireless network. This allows other wireless devices  
to scan and establish communication with the device. Unchecking this  
option hides the SSID to prevent other wireless devices from recognizing and  
connecting to the device.  
Station  
Any device containing IEEE 802.11 wireless medium access conformity.  
Subnet Mask  
A subnet mask is a set of four numbers configured like an IP address. It is used  
to create IP address numbers used only within a particular network.  
TCP (Transmission Control Protocol)  
The standard transport level protocol that provides the full duplex, stream  
service on which many application protocols depend. TCP allows a process  
or one machine to send a stream of data to a process on another. Software  
implementing TCP usually resides in the operating system and uses the IP to  
transmit information across the network.  
WAN (Wide Area Network)  
A system of LANs, connected together. A network that connects computers  
located in separate areas, (i.e., different buildings, cities, countries). The Internet  
is a wide area network.  
WECA (Wireless Ethernet Compatibility Alliance)  
An industry group that certifies cross-vender interoperability and compatibility  
of IEEE 802.11b wireless networking prod WPA (Wi-Fi Protected Access)  
WPA (Wi-Fi Protected Access)  
Wi-Fi Protected Access (WPA) is an improved security system for 802.11. It is  
part of the 802.11i draft security standard. WPA encompasses TKIP (Temporal  
Key Integrity Protocol) along with MIC (Message Integrity Check) and other  
fixes to WEP such as Weak IV (Initialization Vector) filtering and Random IV  
generation. TKIP uses 802.1x to deploy and change temporary keys as opposed  
to static WEP keys once used in the past. It is a significant improvement  
over WEP. WPA is part of a complete security solution. WPA also requires  
authentication servers in enterprise security solutions.  
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Requirements  
(1) A WPA compatible Access Point or Wireless router, (2) Operating system  
updates that support WPA. In XP, an updated Windows Zero Config service is  
needed. Users can download the Windows XP WPA patch here:  
ABEC-274845DC9E91&displaylang=en  
Please note that this patch requires the installation Windows XP Service  
downloads/servicepacks/sp1/default.asp  
For earlier Windows Operating systems, a WPA capable supplicant is required  
such as Funk Software’s Odyssey Client.  
WLAN (Wireless Local Area Network)  
This is a group of computers and other devices connected wirelessly in a small  
area. A wireless network is referred to as LAN or WLAN.  
19  
Notices  
Federal Communications Commission  
This device complies with FCC Rules Part 15. Operation is subject to the  
following two conditions:  
This device may not cause harmful interference, and  
This device must accept any interference received, including interference  
that may cause undesired operation.  
This equipment has been tested and found to comply with the limits for a class  
B digital device pursuant to part 15 of the FCC Rules. These limits are designed  
to provide reasonable protection against harmful interference in a residential  
installation. This equipment generates, uses and can radiate radio frequency  
energy and, if not installed and used in accordance with the instructions, may  
cause harmful interference to radio communications. However, there is no  
guarantee that interference will not occur in a particular installation. If this  
equipment does cause harmful interference to radio or television reception,  
which can be determined by turning the equipment off and on, the user is  
encouraged to try to correct the interference by one or more of the following  
measures:  
Reorient or relocate the receiving antenna.  
Increase the separation between the equipment and receiver.  
Connect the equipment into an outlet on a circuit different from that to  
which the receiver is connected.  
Consult the dealer or an experienced radio/TV technician for help.  
WARNING: Any changes or modifications not expressly approved by  
the party responsible for compliance could void the user’s authority to  
operate the equipment.  
Operate the device in 5150-5250MHz frequency band for indoor use only.  
Prohibition of Co-location  
This device and its antenna(s) must not be co-located or operating in  
conjunction with any other antenna or transmitter.  
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FCC Radiation Exposure Statement  
This equipment complies with RFCC radiation exposure limits set forth for an  
uncontrolled environment .  
This equipment should be installed and operated with minimum 20cm  
between the radiator and your body.  
CE Mark Warning  
This is a Class B product, in a domestic environment, this product may cause  
radio interference, in which case the user may be required to take adequate  
measures.  
Operation Channels: Ch1~11 for N. America, Ch1~14 Japan, Ch1~ 13 Europe  
(ETSI)  
DGT Warning Statement  
Article 12  
Without permission, any company, firm or user shall not alter the frequency,  
increase the power, or change the characteristics and functions of the original  
design of the certified lower power frequency electric machinery.  
Article 14  
The application of low power frequency electric machineries shall not affect  
the navigation safety nor interfere a legal communication, if an interference  
is found, the service will be suspended until improvement is made and the  
interference no longer exists.  
低功率電波輻射性電機管理辦法  
(1)「經型式認證合格之低功率射頻電機經許可號或使用者均不得擅自變更頻率、  
加大功率或變更原設計之特性及功能」以及 (2)「低功率射頻電機之使用不得影響飛航安全及  
干擾合法通信;經發現有干擾現象時,應立即停用,並改善至無干擾時方得繼續使用。前項合  
法通信,指依電信法規定作業之無線電通信。低功率射頻電機須忍受合法通信或工業、科學及  
醫療用電波輻射性電機設備之干擾。  
21  
IC Warning Statement  
Under Industry Canada regulations, this radio transmitter may only operate  
using an antenna of a type and maximum (or lesser) gain approved for the  
transmitter by Industry Canada. To reduce potential radio interference to other  
users, the antenna type and its gain should be so chosen that the equivalent  
isotropically radiated power (e.i.r.p.) is not more than that necessary for  
successful communication.  
This radio transmitter(IC: 3568A-USBAC51) has been approved by Industry  
Canada to operate with the antenna types listed below with the maximum  
permissible gain and required antenna impedance for each antenna type  
indicated. Antenna types not included in this list, having a gain greater than  
the maximum gain indicated for that type, are strictly prohibited for use with  
this device.  
This Class [B] digital apparatus complies with Canadian ICES-003.  
Cet appareil numérique de la classe [B] est conforme à la norme NMB-003 du Canada.  
For product available in the USA/Canada market, only channel 1~11 can be operated.  
Selection of other channels is not possible.  
IC Radiation Exposure Statement:  
This equipment complies with IC RSS-102 radiation exposure limits set forth for  
an uncontrolled environment. This equipment should be installed and operated  
with minimum distance 20cm between the radiator & your body.  
Operation is subject to the following two conditions: (1) this device may not  
cause interference, and (2) this device must accept any interference, including  
interference that may cause undesired operation of the device.  
22  
Canada, avis d’Industry Canada (IC)  
Cet appareil numérique de classe B est conforme aux normes canadiennes  
ICES-003 et RSS-210.  
Son fonctionnement est soumis aux deux conditions suivantes : (1) cet  
appareil ne doit pas causer d’interférence et (2) cet appareil doit accepter  
toute interférence, notamment les interférences qui peuvent affecter son  
fonctionnement.  
Informations concernant lexposition aux fréquences radio (RF)  
La puissance de sortie émise par l’appareil de sans fil Dell est inférieure à  
la limite d’exposition aux fréquences radio d’Industry Canada (IC). Utilisez  
l’appareil de sans fil Dell de façon à minimiser les contacts humains lors du  
fonctionnement normal.  
Ce périphérique a été évalué et démontré conforme aux limites SAR (Specific  
Absorption Rate – Taux d’absorption spécifique) d’IC lorsqu’il est installé  
dans des produits hôtes particuliers qui fonctionnent dans des conditions  
d’exposition à des appareils portables (les antennes se situent à moins de 20  
centimètres du corps d’une personne). Ce périphérique est homologué pour  
l’utilisation au Canada. Pour consulter l’entrée correspondant à l’appareil dans  
la liste d’équipement radio (REL - Radio Equipment List) d’Industry Canada  
rendez-vous sur:  
Pour des informations supplémentaires concernant l’exposition aux RF au  
html  
ASUS Recycling/Takeback Services  
ASUS recycling and takeback programs come from our commitment to the  
highest standards for protecting our environment. We believe in providing  
solutions for you to be able to responsibly recycle our products, batteries, other  
com/english/Takeback.htm for the detailed recycling information in different  
regions.  
REACH  
Complying with the REACH (Registration, Evaluation, Authorisation, and  
Restriction of Chemicals) regulatory framework, we published the chemical  
english/REACH.htm.  
23  
ASUS Contact Information  
ASUSTeK COMPUTER INC. (Asia Pacific)  
Address  
Website  
15 Li-Te Road, Peitou, Taipei, Taiwan 11259  
Technical Support  
Telephone  
Support Fax  
+886228943447  
+886228907698  
support.asus.com  
Online support  
ASUS COMPUTER INTERNATIONAL (America)  
Address  
Telephone  
Fax  
Website  
Online support  
800 Corporate Way, Fremont, CA 94539, USA  
+15029550883  
+15029338713  
usa.asus.com  
support.asus.com  
ASUS COMPUTER GmbH (Germany and Austria)  
Address  
Harkort Str. 21-23, D-40880 Ratingen,  
Germany  
Fax  
+492102959911  
Website  
Online contact  
Technical Support  
Telephone (Component)  
+491805010923*  
Telephone (System/Notebook/Eee/LCD) +491805010920*  
Fax  
+492102959911  
Online support  
support.asus.com  
* EUR 0.14/minute from a German fixed landline; EUR 0.42/minute from a mobile phone.  
24  
Manufacturer ASUSTeK Computer Inc.  
Tel: +886-2-2894-3447  
Address: 4F., No. 150, LI-TE RD., PEITOU, TAIPEI 112, TAIWAN  
Authorised  
representative  
in Europe  
ASUS Computer GmbH  
Address: HARKORT STR. 21-23, 40880 RATINGEN, GERMANY  
Authorised  
distributors in  
Turkey  
BOGAZICI BIL GISAYAR SAN. VE TIC. A.S.  
Tel: +90 212 3311000  
Address: AYAZAGA MAH. KEMERBURGAZ CAD. NO.10 AYAZAGA/  
ISTANBUL  
CIZGI Elektronik San. Tic. Ltd. Sti.  
Tel: +90 212 3567070  
Address: CEMAL SURURI CD. HALIM MERIC IS MERKEZI  
No: 15/C D:5-6 34394 MECIDIYEKOY/ ISTANBUL  
KOYUNCU ELEKTRONiK BiLGi iSLEM SiST. SAN. VE DIS TIC. A.S.  
Tel: +90 216 5288888  
Address: EMEK MAH.ORDU CAD. NO:18, SARIGAZi, SANCAKTEPE  
ISTANBUL  
AEEE Yönetmeliğine Uygundur.  
25  
26  

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