ANT-LTE-CER-T

## **ANT-LTE-CER Data Sheet** 

## Product Description 

The CER Series LTE ceramic chip antenna is a compact, high efficiency antenna designed to be easily integrated into wireless telecommunication devices. Operating in all common 4G/3G/2G LTE bands, it has better efficiency and gain at lower cellular bands compared to competitive products, providing enhanced performance for NB-IoT (Narrow Band Internet of Things) applications. The CER Series antenna’s small size saves valuable board space and the integrated solution saves time and money for labor, cable, and connector costs during installation or deployment. 

## Features 

Covers all common 4G/3G/2G LTE bands High efficiency and gain at the lower bands for CAT-M1 and NB-IoT applications Small, surface mount package is ideal for integration in small devices 

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37.0±0.25 mm 5.0±0.15 mm<br>(1.457±0.010") (0.197±0.006")<br>—__!—+_—_—_—_———>| <—|<br>AT LTECER [|<br>5.0±0.15 mm<br>(0.197±0.006")<br>**----- End of picture text -----**<br>


## Ordering Information 

ANT-LTE-CER-B (supplied in cut tape) ANT-LTE-CER-T (Tape and reel of 450 pieces) 

AEK-LTE-CER (Evaluation Kit) 

|Recommended Frequency<br>Range|LTE/ GSM850/ GSM900|DCS/ PCS/ UMTS1|LTE 2300|LTE 2600|
|---|---|---|---|---|
||698 – 960|1710 – 2170|2300 – 2400|2500 – 2700|
|VSWR|<4:1|<3.2:1|<2.5:1|<2.5:1|
|Peak Gain|3.5dBi|4.0dBi|3.75dBi|3.0dBi|
|Average Gain|–2.77dBi|–1.72dBi|–1.23dBi|–2.04dBi|
|Efficiency|55%|75%|75%|65%|
|Polarization|Linear||||
|Radiation|Omni-Directional||||
|Wavelength|¼-wave||||
|Impedance|50-ohms||||
|Connection|Surface-mount||||
|Weight|3g (0.1oz)||||
|Operating Temperature Range|–40°C to +85°C||||
|Storage Temperature Range|–40°C to +85°C||||
|Relative Humidity|+40˚C, 0-95% r.h.||||
|Polarization|Linear||||
|Electrical specifications and plots measured with a 45mm x 120mm (1.77” x 4.72”) reference ground plane.|||||



Revised 2/20/2018 

– **1** – 

## VSWR Graph 

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0.69 0.96 1.71 2.17 2.3 2.4 2.5 2.7<br>6 51<br>5<br>4 36<br>3<br>2 11<br>1 0<br>0.60 1.00 1.40 1.80 2.20 2.60 3.00<br>Frequency [GHz]<br>VSWR<br>Reflected Power (%)<br>**----- End of picture text -----**<br>


## Return Loss 

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0.69 0.96 1.71 2.17 2.3 2.4 2.5 2.7<br>0<br>-2<br>-4<br>-6<br>-8<br>-10<br>-12<br>-14<br>-16<br>-18<br>-20<br>-22<br>0.60 1.00 1.40 1.80 2.20 2.60 3.00<br>Frequency [GHz]<br>dB<br>**----- End of picture text -----**<br>


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ANT-LTE-CER Data Sheet 

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## Gain Plots 

XZ-Plane Gain 

YZ-Plane Gain 

XY-Plane Gain 

## 700 - 960MHz 

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340 350 5.00 0 10 20 340 350 5.00 0 10 20 340 350 5.00 0 10 20<br>330 0.00 30 330 0.00 30 330 0.00 30<br>320 -5.00 40 320 -5.00 40 320 -5.00 40<br>-10.00 -10.00 -10.00<br>310 -15.00 50 310 -15.00 50 310 -15.00 50<br>300 -20.00 60 300 -20.00 60 300 -20.00 60<br>-25.00 -25.00 -25.00<br>290 -30.00 70 290 -30.00 70 290 -30.00 70<br>-35.00 -35.00 ~ -35.00<br>280 -40.00 80 280 -40.00 80 280 -40.00 80<br>-45.00 -45.00 -45.00<br>270 -50.00 90 270 -50.00 90 270 -50.00 90<br>260 100 260 100 260 100<br>250 110 250 110 250 110<br>240 120 240 120 240 120<br>230 130 230 130 230 130<br>220 140 220 140 220 140<br>210 150 210 150 210 150<br>200 190 180 170 160 200 190 180 170 160 200 190 180 170 160 700MHz830MHz<br>XZ-Plane Gain YZ-Plane Gain XY-Plane Gain 960MHz<br>1710 - 2170MHz<br>340 350 5.00 0 10 20 340 350 5.00 0 10 20 340 350 5.00 0 10 20<br>330 0.00 30 330 0.00 30 330 0.00 30<br>320 -5.00 40 320 -5.00 40 320 -5.00 40<br>-10.00 -10.00 -10.00<br>310 -15.00 50 310 -15.00 50 310 -15.00 50<br>300 -20.00 60 300 -20.00 60 300 -20.00 60<br>-25.00 -25.00 -25.00<br>290 -30.00 70 290 -30.00 70 290 -30.00 70<br>-35.00 -35.00 -35.00<br>280 -40.00 80 280 -40.00 80 280 -40.00 80<br>-45.00 -45.00 -45.00<br>270 -50.00 90 270 -50.00 90 270 -50.00 90<br>260 100 260 100 260 100<br>250 110 250 110 250 110<br>240 120 240 120 240 120<br>230 130 230 130 230 130<br>O 220 140 220 e 140 220 140<br>210 AA 150 210 WAS 150 210 150<br>200 190 180 170 160 200 190 180 170 160 200 190 180 170 160 1710MHz1940MHz<br>XZ-Plane Gain YZ-Plane Gain XY-Plane Gain = 2170MHz<br>**----- End of picture text -----**<br>


ANT-LTE-CER Data Sheet 

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## Gain Plots 

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XZ-Plane Gain<br>**----- End of picture text -----**<br>


## YZ-Plane Gain 

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XY-Plane Gain<br>**----- End of picture text -----**<br>


## 2300 - 2400MHz 

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340 350 5.00 0 10 20 340 350 5.00 0 10 20 340 350 5.00 0 10 20<br>330 0.00 30 330 0.00 30 330 0.00 30<br>320 -5.00 40 320 -5.00 40 320 -5.00 40<br>-10.00 -10.00 -10.00<br>310 -15.00 50 310 -15.00 50 310 -15.00 50<br>300 -20.00 60 300 -20.00 60 300 -20.00 60<br>-25.00 -25.00 -25.00<br>290 -30.00 70 290 -30.00 70 290 -30.00 70<br>-35.00 -35.00 -35.00<br>280 -40.00 80 280 -40.00 80 280 -40.00 80<br>-45.00 -45.00 -45.00<br>270 -50.00 90 270 -50.00 90 270 -50.00 90<br>260 100 260 100 260 100<br>250 110 250 110 250 110<br>240 120 240 120 240 120<br>230 130 230 130 230 130<br>220 140 220 140 220 140<br>210 150 210 150 210 150<br>200 190 180 170 160 200 190 180 170 160 200 190 180 170 160 2300MHz2350MHz<br>XZ-Plane Gain YZ-Plane Gain XY-Plane Gain 2400MHz<br>**----- End of picture text -----**<br>


## 2500 - 2700MHz 

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340 350 5.00 0 10 20 340 350 5.00 0 10 20 340 350 5.00 0 10 20<br>330 0.00 30 330 0.00 30 330 0.00 30<br>320 -5.00 40 320 -5.00 40 320 -5.00 40<br>-10.00 -10.00 -10.00<br>310 -15.00 50 310 -15.00 50 310 -15.00 50<br>300 -20.00 60 300 -20.00 60 300 -20.00 60<br>-25.00 -25.00 -25.00<br>290 -30.00 70 290 -30.00 70 290 -30.00 70<br>-35.00 -35.00 -35.00<br>280 -40.00 80 280 -40.00 80 280 -40.00 80<br>-45.00 -45.00 -45.00<br>270 -50.00 90 270 -50.00 90 270 -50.00 90<br>260 100 260 100 260 100<br>250 110 250 110 250 110<br>240 120 240 120 240 120<br>230 130 230 130 230 130<br>220 140 220 140 220 140<br>210 150 210 150 210 150<br>200 190 180 170 160 200 190 180 170 160 200 190 180 170 160 2500MHz2600MHz<br>XZ-Plane Gain YZ-Plane Gain XY-Plane Gain 2700MHz<br>**----- End of picture text -----**<br>


ANT-LTE-CER Data Sheet 

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## Peak Gain 

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0.69 0.96 1.71 2.17 2.3 2.4 2.5 2.7<br>8<br>6<br>4<br>2<br>0<br>-2<br>-4<br>-6<br>-8<br>-10<br>0.60 1.00 1.40 1.80 2.20 2.60 3.00<br>Frequency [GHz]<br>Gain (dBi)<br>**----- End of picture text -----**<br>


## Average Gain 

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0.69 0.96 1.71 2.17 2.3 2.4 2.5 2.7<br>1<br>-1<br>-3<br>-5<br>-7<br>-9<br>-11<br>-13<br>-15<br>0.60 1.00 1.40 1.80 2.20 2.60 3.00<br>Frequency [GHz]<br>Gain (dBi)<br>**----- End of picture text -----**<br>


## ������������������� 

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0.69 0.96 1.71 2.17 2.3 2.4 2.5 2.7<br>100<br>90<br>80<br>70<br>60<br>50<br>40<br>30<br>20<br>10<br>0<br>0.60 1.00 1.40 1.80 2.20 2.60 3.00<br>Frequency [GHz]<br>Efficiency (%)<br>**----- End of picture text -----**<br>


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ANT-LTE-CER Data Sheet 

– **5** – 

## Matching Network 

The antenna requires a matching network for optimum performance.  This network allows the antenna’s response to be optimized for each board, taking into account the PCB layout, other components in the device and the enclosure. 

The evaluation board requires two components for a proper match; a series capacitor and a shunt inductor. 

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C1<br>Radio<br>L1<br>GND<br>Matching Network<br>Designator Size Description<br>L1 0402 6.8nH Inductor (Taiyo Yuden HK10056N8S-T)<br>C1 0402 3pF Capacitor (Murata Electronics GRM1555C1H3R0CA01D)<br>**----- End of picture text -----**<br>


The final product design may change the performance due to the components on the board, different PCB material and layout, and the enclosure around the antenna. It may be necessary to adjust these values to match the specific board. 

The performance is critically dependent on many variables, so it is generally not possible to estimate the performance before fabricating the board. Testing on the final board is needed to determine the final values. Linx can help with this tuning if needed. Please contact us for more information. 

need additional tuning. In these cases it is recommended to add pads for a full matching network, as shown below. It is likely that not all of the elements will be needed in the final tuning, but having the pads provides the options to place them if necessary. Testing on the final board is needed to determine which elements are required and what their values should be. 

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C1<br>Radio<br>GND GND GND<br>**----- End of picture text -----**<br>


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ANT-LTE-CER Data Sheet 

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45.0mm<br>2.5mm 2.5mm<br>4.0mm 4.0mm<br>32.0mm<br>1.0mm<br>ees |<br>1.2mm<br>0.5mm<br>0.5mm<br>6.0mm 1.5mm 6.0mm<br>1.65mm 1.65mm<br>2.0mm<br>1.5mm L1 6.0mm 1.5mm<br>24.65mm 4.0mm<br>16.2mm<br>Beee ,yy<br>e e e e e e e e e | e e e e e e<br>0.5mm<br>1.0mm<br>0.5mm<br>50Ω Trace<br>0.5mm<br>C1<br>**----- End of picture text -----**<br>


|**Matching Network**<br>~~FT~~|**Matching Network**<br>~~FT~~|
|---|---|
|Designator<br>Size|Description|
|L1<br>0402|6.8nH Inductor (Taiyo Yuden HK10056N8S-T)|
|C1<br>0402|3pF Capacitor (Murata Electronics GRM1555C1H3R0CA01D)|



ANT-LTE-CER Data Sheet 

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45.0mm<br>2.5mm 2.5mm<br>4.0mm 4.0mm<br>32.0mm<br>1.0mm<br>a es |<br>1.2mm<br>0.5mm<br>0.5mm<br>6.0mm 1.5mm 6.0mm<br>1.65mm 1.65mm<br>2.0mm<br>1.5mm L1 6.0mm 1.5mm<br>24.65mm 4.0mm<br>16.2mm<br>Be ge<br>eeeeeee 1.5mm e<br>0.5mm<br>e e e e 1.5mm e | | e e e e<br>||<br>1.5mm<br>e e e e e e e e<br>] ]<br>1.0mm<br>0.5mm<br>50Ω Trace<br>0.5mm<br>C1<br>**----- End of picture text -----**<br>


Component values are determined through testing. Contact Linx for more information on matching network assistance. 

ANT-LTE-CER Data Sheet 

**– 8** – 

## ���������������������������������������� 

The PCB layout is critical to the antenna’s successful implementation. The following guidelines should be followed to get the optimum performance out of the antenna. 

- �� Use a manufactured board for testing the antenna performance. RF is very picky and perf boards or other “hacked” boards will at best give a poor indication of the antenna’s true performance and at worst will simply not work.  The recommended layout that should be followed as closely as possible to get the specified performance. An evaluation kit that includes a test board is available, so please contact us for details. 

- �� The antenna should, as much as reasonably possible, be isolated from other components on the PCB, especially high-frequency circuitry such as crystal oscillators, switching power supplies, and high-speed bus lines. Everything in the antenna’s near field (within one wavelength) has an impact on the radiation pattern and performance, so the antenna needs to be on its own. This is contrary to much of today’s designs where everything is compacted as much as possible, but it is what is necessary to get the most out of the antenna. 

- �� Keep traces away from the antenna. Traces can become antennas themselves, frequently at a harmonic of the operational frequency. This can cause issues when going for regulatory certifications. This includes traces under the antenna itself on any layer of the board. Unshielded wires and wire harnesses inside the enclosure also need to be kept away for the same reason. Be sure to secure them so that they will not come loose and fall across the antenna. 

- �� The antenna is only half of the complete antenna structure. The other half is a ground plane counterpoise on the circuit board. The dimensions of the plane are critical to the antenna’s performance and it should be as solid as possible. It can act as the ground connection for other circuits on the board. More details on the function of the ground plane can be found in application notes AN-00500 and AN-00501. 

- �� The antennas are tuned to be 50 ohms at the frequency of operation. The connection to the radio needs to be a single-ended 50-ohm transmission line. This is typically either a microstrip line or a co-planar waveguide. 

- �� The product’s enclosure needs to be non-conductive. Embedded antennas cannot be used effectively in metal, carbon fiber or some fiberglass enclosures.  Placing non-conductive panels in metal enclosures does allow some signal to get out in the direction of the panel, but has a significant impact on the overall performance. Not only does it potentially reduce the radiated power, it also focuses the power just like a flashlight focuses the light from a bulb. This gives great range during initial testing, but can be a great disappointment when regulatory compliance testing requires the transmitter power to be reduced. This could result in much less range than was achieved during initial testing and greatly affects the product’s performance. 

- �� There should be no traces, planes or any copper under the antenna or to its sides on any layer of the board. Anything conductive in this area will impact the radiation pattern and the antenna’s performance. 

- �� 

- �� The antenna should be placed on the PCB’s shortest edge, allowing the longest dimension to be dedicated to the ground plane counterpoise. 

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ANT-LTE-CER Data Sheet 

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45.0 mm<br>(1.772 in)<br>13.0 mm<br>(0.512 in) 6.0 mm<br>(0.236 in)<br>29.5 mm<br>(1.161 in)<br>7 |<br>107.0 mm<br>(4.212 in)<br>**----- End of picture text -----**<br>


ANT-LTE-CER Data Sheet 

**– 10** – 

## ������������������� 

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tP<br>Critical Zone<br>TP TL to TP<br>Ramp-up<br>TL tL<br>TS max<br>TS min<br>tS Ramp-down<br>Preheat<br>25°<br>t 25° to Peak<br>Temperature<br>**----- End of picture text -----**<br>


Time 

|Ramp-up|Avg. Ramp-up Rate (Tsmax to TP)|3°C per second (max)|3°C per second (max)|
|---|---|---|---|
|Preheat|Temperature Min (TSmin)<br>Temperature Max (TSmin)<br>Time (tsmin to tsmax)|100°C<br>150°C<br>60 to 120 seconds|100°C<br>150°C<br>60 to 120 seconds|
|Refow|Temperature(TL)<br>Total Time above TL (tL)|183°C<br>60 to 150 seconds|217°C<br>60 to 150 seconds|
|Peak|Temperature(TP)<br>Time(tp)|235°C<br>10 to 30 seconds|260°C<br>20 to 40 seconds|
|Ramp-down|Rate|6°C per second (max)|6°C per second (max)|
|Time from 25°C to Peak Temperature||6 minutes max|8 minutes max|



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ANT-LTE-CER Data Sheet 

– **11** – 

## ����������������������� 

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4.0±0.1<br>(0.157±0.004)<br>2.0±0.1<br>Ø1.5 +0.1-0.0 (0.079±0.004) 1.75±0.1 0.40±0.05<br>(0.059      )+0.004-0.000 (0.069±0.004) (0.016±0.002)<br>R0.30 MAX<br>(0.012)<br>3°<br>12±0.1 5.4<br>(0.472±0.004) (0.213)<br>3°<br>5.4±0.1<br>(0.213±0.004)<br>5.4±0.1<br>(0.213±0.004)<br>Ø13.0+1.0-0.0<br>+0.039<br>(0.512      )-0.000<br>2.2±0.3<br>(0.087±0.012)<br>56.0±1.0<br>(2.205±0.039)<br>)<br>)<br>26.2±0.1<br>1.031±0.004<br>(<br>)<br>56.0±0.3 37.4±0.1<br>2.205±0.012<br>( (1.472±0.004)<br>52.4±0.1<br>2.062±0.004<br>(<br>Ø100 (3.937)<br>Ø330±1.0<br>(12.99±0.039)<br>**----- End of picture text -----**<br>


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ANT-LTE-CER Data Sheet 

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## ���������������������������������������������������� 

A transmission line is a medium whereby RF energy is transferred from one place to another with minimal loss. It is designed for a specific characteristic impedance to match the antenna to the radio. This is a critical factor, especially in high-frequency products because the trace leading to the antenna can effectively contribute to the length of the antenna, changing its resonant frequency. This detuning increases energy loss in the system and reduces overall range of the radio link. In order to minimize loss and detuning, some form of transmission line between the antenna and the radio should be used. There are several kinds of transmission lines but two are commonly used for low-cost embedded radios; a microstrip line and a co-planar waveguide. 

## Microstrip Transmission Lines 

A microstrip is a PCB trace that runs over a ground plane. There are several factors that contribute to its characteristic impedance, but the two most critical ones are distance from the ground plane and width of the trace. The calculations and some examples are shown below. 

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Trace<br>Board<br>Ground plane<br>**----- End of picture text -----**<br>


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|**Example Microstrip Calculations**<br>Dielectric Constant<br>Width / Height Ratio (W / d)<br>Effective Dielectric Constant<br>Characteristic<br>Impedance (�)<br>4.80<br>1.8<br>3.59<br>50.0<br>4.00<br>2.0<br>3.07<br>51.0<br>2.55<br>3.0<br>2.12<br>48.8|**Example Microstrip Calculations**<br>Dielectric Constant<br>Width / Height Ratio (W / d)<br>Effective Dielectric Constant<br>Characteristic<br>Impedance (�)<br>4.80<br>1.8<br>3.59<br>50.0<br>4.00<br>2.0<br>3.07<br>51.0<br>2.55<br>3.0<br>2.12<br>48.8|**Example Microstrip Calculations**<br>Dielectric Constant<br>Width / Height Ratio (W / d)<br>Effective Dielectric Constant<br>Characteristic<br>Impedance (�)<br>4.80<br>1.8<br>3.59<br>50.0<br>4.00<br>2.0<br>3.07<br>51.0<br>2.55<br>3.0<br>2.12<br>48.8|**Example Microstrip Calculations**<br>Dielectric Constant<br>Width / Height Ratio (W / d)<br>Effective Dielectric Constant<br>Characteristic<br>Impedance (�)<br>4.80<br>1.8<br>3.59<br>50.0<br>4.00<br>2.0<br>3.07<br>51.0<br>2.55<br>3.0<br>2.12<br>48.8|**Example Microstrip Calculations**<br>Dielectric Constant<br>Width / Height Ratio (W / d)<br>Effective Dielectric Constant<br>Characteristic<br>Impedance (�)<br>4.80<br>1.8<br>3.59<br>50.0<br>4.00<br>2.0<br>3.07<br>51.0<br>2.55<br>3.0<br>2.12<br>48.8|
|---|---|---|---|---|
|4.80||1.8|3.59|50.0|
|4.00||2.0|3.07|51.0|
||2.55|3.0|2.12|48.8|
||||||
||||||



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ANT-LTE-CER Data Sheet 

– **13** – 

## Grounded Coplanar Waveguide 

A grounded coplanar waveguide is a PCB trace that has ground plane on both sides and on a lower layer. This structure allows more precise control over the line impedance and results in smaller trace widths at a 

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GND GND<br>G W G<br>H<br>εr, Tan δ<br>GND<br>**----- End of picture text -----**<br>


given impedance. The calculations for the design get fairly complicated, so online calculators are generally used or calculators built into design software. 

Because the ground plane is on both sides of the trace and on the bottom, it is important to ensure that the planes are at the same impedance. Vias are typically added in rows along the edge of the gaps to connect the top plane to the bottom plane. This is referred to as “fencing” or “stapling”. When adding vias, the rule-of-thumb is to add them at spacings of 1/8 of a wavelength or less. This gives good isolation and makes the ground plane look solid. 

For the best isolation, the rule is to space vias at 1/20 of a wavelength or less. However, this is genearally overkill for most commercial products and the 1/8 rule is more practical. 

Copyright © 2018 Linx Technologies 159 Ort Lane, Merlin, OR 97532 Phone: +1 541 471 6256 Fax: +1 541 471 6251 www.linxtechnologies.com 

ANT-LTE-CER Data Sheet 

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**– 14** – 

## **TE  TECHNICAL SUPPORT CENTER** 

USA: +1 (800) 522-6752 Canada: +1 (905) 475-6222 Mexico: +52 (0) 55-1106-0800 Latin/S. America: +54 (0) 11-4733-2200 Germany: +49 (0) 6251-133-1999 UK: +44 (0) 800-267666 France: +33 (0) 1-3420-8686 Netherlands: +31 (0) 73-6246-999 China: +86 (0) 400-820-6015 

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The information given herein, including drawings, illustrations and schematics which are intended for illustration purposes only, is believed to be reliable. However, TE Connectivity makes no warranties as to its accuracy or completeness and disclaims any liability in connection with its use. TE Connectivity‘s obligations shall only be as set forth in TE Connectivity‘s Standard Terms and Conditions of Sale for this product and in no case will TE Connectivity be liable for any incidental, indirect or consequential damages arising out of the sale, resale, use or misuse of the product. Users of TE Connectivity products should make their own evaluation to determine the suitability of each such product for the specific application. 

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