Complete Solution Clause Samples
The Complete Solution clause defines the supplier's obligation to deliver a fully functional and integrated product or service that meets all specified requirements. In practice, this means the supplier must provide all necessary components, services, and support to ensure the solution operates as intended, even if certain elements are not explicitly listed in the contract. This clause ensures that the customer receives a turnkey solution without unexpected gaps, thereby reducing the risk of incomplete delivery and disputes over missing features or services.
Complete Solution. The Contractor will supply all labor, devices/equipment, and Services necessary to provide the System(s) in accordance with the Purchase Price set forth in Section 3.1. The Contractor represents and warrants that the purchase of the System(s) and installation and implementation Services provided to the District will constitute a fully operational solution as contemplated by the Contract Documentation.
Complete Solution. The PC based scenario engine, launches a number of link layer scenario’s to the Device Under Test [DUT] and reference devices through the Test board. This is used to demonstrate the high data rate communication module and is also used to do thorough validation testing. BTLE link layer slave 100 All pass BTLE link layer master 100 All pass BTLE link layer multi-master 50 All pass 802.15.4 basic 50 All pass 802.15.4 complete 50 All pass The demodulator [5 in figure 12] performance has been measured with an RF test chip [external to this project]. Results show great sensitivity and power consumption. In figure 17 sensitivities 10000 BlueICe_GFSK BlueICe QPSK #1 #5 -97 #2 1000 #3 #1 #4 #5 #7 #6 100 -115 -110 -105 -100 -95 -90 -85 #9 #10 #1 -95 0 -88 -92,5 -91 -96 #2 #3 #6 #4 #7 -93 -91 are given, compared to present market available solutions. Very significant improvement over the state of the art has been shown. The PHY power consumption/performance combination results are outstanding. This has been also achieved through advanced RTL design methods. In table 3 a summary of the demodulator power consumption is its most important modes. Manual Clock Gating 51655 480 361 380 11 305 The packet processor platform power consumption is also outstanding. This is due to [1] its architecture which only keeps the LINK processor active for a short time and typically not when the radio is active, [2] the very low power consumption for the BLUSP processor and [3] the BLUSP performance which allows to keep the clock frequency very low. To demonstrate this the power consumption for a BTLE RX – TX combination is calculated and compared to 2 industry examples. 410μS 150μS 410μS 150μS 410μS 150μS Tifs Tifs Tifs "on air" RX TX RX Current consumption[1] 10μA 350μA 1mA 10μA 10μA 90μA 1mA 10μA 10μA 350μA 1mA 10μA 100μS 310μS 95μS 55μS 100μS 310μS 95μS 55μS 100μS 310μS 95μS 55μS This current profile is based on RTL simulation for a TSMC 90nm CMOS reference process. The total digital energy for a 32Byte BTLE packet equals 0.2 μJ [RX] and 0.12 μJ [TX] = 0.32 μJ for an RX-TX. Compared this to 2 typical commercial solution [Figure 19]: solution-1: [ 65 μJ RX-TX]; solution-2: [ 15 μJ RX-TX]; these commercial solutions include also RF power consumption. The digital consumption developed solution consumes less than 2.5% of the commercial solutions. The commercial solutions include the RF current. In the 2 solutions the RF current is estimated at 75% of the overall current. So an improvemen...