search.noResults

search.searching

dataCollection.invalidEmail
note.createNoteMessage

search.noResults

search.searching

orderForm.title

orderForm.productCode
orderForm.description
orderForm.quantity
orderForm.itemPrice
orderForm.price
orderForm.totalPrice
orderForm.deliveryDetails.billingAddress
orderForm.deliveryDetails.deliveryAddress
orderForm.noItems
INDUSTRY FOCUS MILITARY, AEROSPACE & DEFENCE


THE CHALLENGE: MODERNISING DEFENCE COMMUNICATIONS SYSTEMS


Military communications (MILCOM) have been the backbone for deployed soldiers since the Vietnam War, but the next generation will need to use modern communication technologies that will enable the delivery of data such as mapping, images and video to a soldier in the battlefield. Wyatt Taylor, aerospace and defence system engineering lead at Analog Devices, explains


M


ILCOM units have proven their capability and security for decades. The next


generation of MILCOM platforms will, however, need to leverage the more modern communication technologies that have been developed to enable commercial platforms such as cell phones and Wi-Fi. The units are often handheld ‘walkie talkies’


featuring a push to talk (PTT) button. When this button is not depressed, an incoming voice message can be received. The voice message relayed between two radios is modulated, encrypted, amplified and transmitted wirelessly between the two soldiers. There are many differences between these


MILCOM walkie talkies and a commercial cell phone or communication system, a few of which can be seen in the table (below).


WHAT CHANGES ARE NEEDED? Next generation MILCOM platforms need to maintain several of these critical differences, while closing some of the gaps between military and commercial communications systems. These will need to change from voice-only systems through the addition of data and text capability, enabling the delivery of data such as mapping, images and video to a soldier in the battlefield. Wider bandwidths, however, create challenges


for the radio platforms, primarily around size, weight and power (SWaP). The traditional radio frequency (RF) signal chains used by MILCOM platforms will not scale to wider bandwidths and digital modulation schemes without consuming much more power, and they will increase size and weight. This is unacceptable to the soldier, who needs a smaller, more capable, radio that can be powered for long mission durations on minimal battery power. Thus, next-generation MILCOM platforms will require new RF signal chain architectures. One revolution in small form factor radio design


has been integrated RF transceivers which reduce size and power by repartitioning the radio in


Feature Bandwidth


Frequency Coverage Frequency Hopping Transmit Power Data Payload Modulation


several ways. First, RF and analog devices can be transferred to the digital domain – RF filters becoming digital filters, for instance. The digital implementations of these blocks are more efficient and more programmable than their RF counterparts. Second, discrete RF signal chains are often heterodyne architectures, which require several layers of frequency conversion, filtering, amplification and digital sampling. Integrated transceivers can use a zero-intermediate frequency (ZIF) architecture that drastically reduces the required components in the signal chain, specifically the required filtering and amplification stages. Removing these stages reduces both size and power. Finally, the ZIF architecture is a more efficient


use of the digital converters which, in a wideband system, can drive overall power consumption. While commercial platforms have been able to take advantage of ZIF transceivers for the last decade, the first products with MILCOM applicable features have only come to market in the last few years. The latest transceiver that can be used in MILCOM systems is the ADRV9009 (see image, above right).


CMOS TRANSCEIVER The ADRV9009 is a CMOS transceiver with several MILCOM appropriate features: 1. The device is a native time duplex device (TDD), which is how a PTT architecture typically operates, and this saves power compared to having two local oscillators (LO) in the device. 2. The integrated LO supports frequency hopping natively in the transceiver, both from a frequency generation perspective, but also from a calibration perspective. 3. The usable bandwidth of the ADRV9009 can


Legacy MILCOM System Commercial System <25 kHz


<500 MHz


Various agility <5 W


Voice only FM, AM, MSK


<20 MHz <6 GHz


Static frequency Typical 0.5 W


Voice, SMS, data, location QAM, QPSK, DSS


Differences between MILCOM and commercial communication systems 28 FEBRUARY 2020 | DESIGN SOLUTIONS


ADRV9009 functional block diagram


be programmed between 20 MHz and 200 MHz, allowing for a range of wide bandwidth operating modes. 4. The ADRV9009 is a waveform agnostic transceiver, meaning that it delivers RF to bits with no limits on what waveform is used. This allows for the ADRV9009 to implement waveforms that are available today, but also to implement waveforms that may be developed in the future. 5. The ADRV9009 integrates several auxiliary features into the transceiver. Automatic gain control (AGC) is critical for optimising the receiver dynamic range, and the ADRV9009 has an internal AGC loop with 30 dB of range. Temperature sensors, control converters, and general-purpose outputs (GPOs) are also integrated into the device, saving space in the radio system. Modernising defence communications


systems is a challenge, and one that will require innovation across a range of engineering disciplines. For the backbone of the radio circuitry, however, integrated transceivers are taking great strides toward providing single-chip solutions that will integrate the bulk of the receiver and transmitter signal chains, while maintaining features such as frequency hopping, AGC, and the capability to upgrade to future waveforms. Building on these transceivers as a core block of the radio will enable the next generation of MILCOM radio systems.


Analog Devices www.analog.com





Page 1  |  Page 2  |  Page 3  |  Page 4  |  Page 5  |  Page 6  |  Page 7  |  Page 8  |  Page 9  |  Page 10  |  Page 11  |  Page 12  |  Page 13  |  Page 14  |  Page 15  |  Page 16  |  Page 17  |  Page 18  |  Page 19  |  Page 20  |  Page 21  |  Page 22  |  Page 23  |  Page 24  |  Page 25  |  Page 26  |  Page 27  |  Page 28  |  Page 29  |  Page 30  |  Page 31  |  Page 32  |  Page 33  |  Page 34  |  Page 35  |  Page 36  |  Page 37  |  Page 38  |  Page 39  |  Page 40  |  Page 41  |  Page 42  |  Page 43  |  Page 44