GB2335798A

GB2335798A - Enhanced bandwidth antenna

Info

Publication number: GB2335798A
Application number: GB9806507A
Authority: GB
Inventors: Olaf Rostbakken
Original assignee: NEC Technologies UK Ltd
Current assignee: NEC Technologies UK Ltd
Priority date: 1998-03-26
Filing date: 1998-03-26
Publication date: 1999-09-29
Anticipated expiration: 2018-03-26
Also published as: GB9806507D0; GB2335798B

Abstract

Patch antennas which are lightweight and occupy a small volume and are therefore especially suitable for mobile phones. The antenna operating bandwidth is switched between transmitter and receiver frequency bands by means of a PIN diode. The PIN diode connects electrically larger and smaller patches which are adjacent to each other on the same substrate but electrically isolated.

Description

2335798 1 Enhanced bandwidth antennas This invention relates to antennas

and in particular it relates to enhanced bandwidth antennas primarily, though not exclusively, for use with mobile phones.

Low profile enhanced bandwidth PIFA antennas are known from the paper by K L Virga and Y Rahmat-Samii, IEEE Transactions on microwave theory and techniques Vol. 45 No. 10 October 1997. In their paper Virga and Y RahmatSarnii discuss the way in which varactor diodes may be used to connect together electrically, two sections of a PIFA element that are separated physically. Such antennas are, however unsuitable for use with mobile communication systems such as GSM and PCN due to the high level of generation of harmonics caused by the varactor diodes.

Directive antennas contained within mobile phone hand sets need to be light in weight and of as small a volume as possible. Microstrip antennas suit these conditions of light weight and small volume but, for thin substrates have relatively narrow bandwidth.

It is an object of this invention to provide a lightweight patch antenna of small volume,, suitable for use with mobile phone hand sets.

According to the invention there is provided a microstrip antenna comprising a larger patch and a smaller patch, both patches formed on the 2 same substrate and the larger and smaller patches connected by a PIN diode and means for applying a voltage to the PIN diode to connect electrically the larger and smaller patches.

According to a further aspect of the invention there is provided a dual band microstrip antenna having a higher frequency antenna and a lower frequency antenna, both antennas formed on the same substrate and each comprising a larger patch and a smaller patch connected by a PIN diode and means for applying a voltage to the PIN diodes to connect electrically the larger and smaller patches.

Two embodiments of the invention will now be explained with reference to the accompanying figures in which:

figure 1 is a plan view of a switchable patch antenna, figure 2 is a side view of the antenna of figure 1, figure 3 is a plan view of a dual band switchable antenna, figure 4 is a side view of the antenna of figure 3.

A first embodiment of the invention is illustrated in figures 1 and 2. The antenna of figures 1 and 2 is for incorporation in a mobile phone which is designed to operate with a single communications system e.g. GSM.

3 With reference to figures 1 and 2, a primary patch 1 is formed on substrate 2 with a feed at 3 and a ground plane at 14. The secondary patch 5 may be switched to connect electrically with primary patch 1 by the application of a voltage (e.g. 3 volts) at 6. A voltage applied at 6 will cause the PIN diode to change from open circuit to short circuit.

Electrical connection of secondary patch 5 to primary patch 1 changes the effective length and consequently the resonant frequency of the patch antenna 1 to provide an antenna suitable for use in a different frequency band. It has been found that PIN diodes as used in this embodiment do not cause unacceptable generation of harmonics.

Therefore instead of the more usual broad antenna bandwidth required to cover the complete range of frequencies for receiver, transmitter and guardband, effectively two antennas of relatively narrow bandwidth are deployed. By means of the switching of PIN diode 4 the antenna operates either in the transmitter band or in the receiver band. Each of the two operating conditions require therefore only a narrow bandwidth.

The thickness (depth) of substrate 2 has an effect on antenna bandwidth such that the thicker the substrate the greater the bandwidth. If required a matching network can be used between the feed 3 and primary patch 1 to increase the bandwidth.

4 A further embodiment of the invention is illustrated in figures 3 and 4. The antenna of figures 3 and 4 is a switchable quarter wave microstrip antenna for incorporation in a so called dual band mobile phone. Dual band phones are designed to be capable of operation with two different communications systems e.g. GSM and PCN.

With reference to figures 3 and 4, two separate switchable antennas are formed on substrate 2. The first antenna, the GSM antenna, comprises a primary patch 1 and secondary patch 5 with a feed at 3. A PIN diode 4 is switched from open circuit to short circuit by the application of a voltage at 6. In this embodiment the shorting pins 7 along one edge of patch 1 are included to reduce the length of the antenna.

The second antenna shown in figures 3 and 4, the PCN antenna, comprises a primary patch 8, a secondary patch 9 and has a feed at 12. The PIN diode 10 is switched from open circuit to short circuit by the application of a voltage at 11. One edge of primary patch 8 is short circuited by shorting -Pins 13.

Claims

1. A a microstrip antenna comprising a larger patch and a smaller patch, both patches formed on the same substrate and the larger and smaller patches connected by a PIN diode and means for applying a voltage to the PIN diode to connect electrically the larger and smaller patches.

2. A dual band microstrip antenna having a higher frequency antenna and a lower frequency antenna, both antennas formed on the same substrate and each comprising a larger patch and a smaller patch connected by a PIN diode and means for applying a voltage to the PIN diodes to connect electrically the larger and smaller patches.

3. A microstrip antenna as in claims 1 or 2 where the antennas are quarter wave resonant patch antennas.

4. A microstrip antenna as in any previous claim where a matching circuit is included between the antenna and the antenna feed.

5. A microstrip antenna as in any previous claim where one edge of the antenna is short circuited.