Abstract: A piston pump group for a brake system and a control method thereof are provided, and the piston pump group includes: a piston, a pump body provided with an operating chamber, and a transmission mechanism used for driving the piston to move in the operating chamber, where the transmission mechanism includes a lead screw transmission assembly, a follower, and a planetary gear assembly used for transmitting power to the lead screw transmission assembly, the follower is fixedly connected to the piston, the lead screw transmission assembly is used for driving the follower to move relative to the operating chamber, and a limiting member used for limiting the movement of the follower is disposed between the lead screw transmission assembly and the follower.

Abstract: The present invention discloses a narrow band slot antenna with a coupling suppression. The slot antenna includes a medium plate (1), a copper-clad layer (2), an A-capacitor (3), and a B-capacitor (4). The copper-clad layer (2) has an A-slot (21) and a B-slot (22) thereon, the A-capacitor (3) and the B-capacitor (4) are respectively mounted inside and at two ends of the B-slot (22). The present invention loads the capacitors at a specific position on a finite medium plate to increase the isolation between the antennas, which is beneficial to rectify the slot antenna.

Abstract: A transient IR-drop waveform measurement system and method for a high speed integrated circuit are provided. The system includes all-digital elements and is based on a ring oscillator in GHz. Through oscillation with a Fast Ring Oscillator, sampling with an Edge Detector and counting with a Ripple Counter, a width and a peak of an IR-drop waveform are obtained. Moreover, a power supply network is adapted during a clock cycle through sending an adaptation signal to a connected dynamic voltage frequency scaling (DVFS) system. The measurement method includes 11 steps. The measurement system has following features: 1) IR-drop peak/width measurement ability; 2) low fabrication and test cost; 3) high accuracy and sensitivity; 4) early adaptation ability. Therefore, the measurement system can be used alone for chip monitoring or testing, in order to reduce a power supply noise disturbance to a chip.

Abstract: An out-of-band coupled antenna combined by fine-and-straight antenna and bow-tie antenna is provided, including: a dielectric slab (1), an AA radiation element (2) provided on an upper plate (1A) of the dielectric slab (1) by a, a cooper pouring process, a BA radiation element (3), an A feeder line (4) and a B feeder line (5); an AB radiation element (8) provided on a lower plate (1B) of the dielectric slab (1), a BB radiation element (9), a C feeder line feeder (6) and a D feeder line (7); a first sensor (10A) and a second sensor (10B) which are connected on the AA radiation element (2); a third sensor (10C) and a fourth sensor (10D) which are connected on the AB radiation element (8). The antenna is capable of suppressing out-of-band coupling between indication elements to improve the separation degree.

Abstract: An impedance compensation structure for a broadband near-field magnetic-field probe, includes: a signal via; and a plurality of grounding vias provided around the signal via to form a coaxial via array; wherein the grounding via and the signal via have an identical size, all distances of each of the plurality of the grounding vias to the signal via are equal, and the plurality of the grounding vias forms a circle centered at the signal via; wherein each of the plurality of the grounding vias is connected with a magnetic field probe top layer shield plane and a magnetic field probe bottom layer shield plane; each of the plurality of the grounding vias keeps in a conducting state from a direct current to a high frequency, in such a manner that impedance matching of the broadband near-field magnetic-field probe is achieved.

Abstract: The resonance structure is that two rows of ground via holes are placed symmetrically along two sides of the CB-CPW central conductor; each row of the via holes are equally spaced; every via hole connects a top shield plane layer, a first middle layer and a bottom shield plane layer of the magnetic probe; every via hole is placed out of a rectangle gap at the bottom of the magnetic probe; the via holes form a fence. The construction method: 1. constructing a simulation model formed by the magnetic probe and a 50? microstrip in a CST® microwave studio; 2. simulation setting; 3. placing via holes along two sides of the central conductor; 4. connecting a 50? matching load to the second end of the microstrip and defining the first end as microstrip port1; defining the end on which mount a SMA connector as probe port2; simulating S21.

Abstract: The present invention discloses a narrow band slot antenna with a coupling suppression. The slot antenna includes a medium plate (1), a copper-clad layer (2), an A-capacitor (3), and a B-capacitor (4). The copper-clad layer (2) has an A-slot (21) and a B-slot (22) thereon, the A-capacitor (3) and the B-capacitor (4) are respectively mounted inside and at two ends of the B-slot (22). The present invention loads the capacitors at a specific position on a finite medium plate to increase the isolation between the antennas, which is beneficial to rectify the slot antenna.

Abstract: An out-of-band coupled antenna combined by fine-and-straight antenna and bow-tie antenna is provided, including: a dielectric slab (1), an AA radiation element (2) provided on an upper plate (1A) of the dielectric slab (1) by a , a cooper pouring process, a BA radiation element (3), an A feeder line (4) and a B feeder line (5); an AB radiation element (8) provided on a lower plate (1B) of the dielectric slab (1), a BB radiation element (9), a C feeder line feeder (6) and a D feeder line (7); a first sensor (10A) and a second sensor (10B) which are connected on the AA radiation element (2); a third sensor (10C) and a fourth sensor (10D) which are connected on the AB radiation element (8). The antenna is capable of suppressing out-of-band coupling between indication elements to improve the separation degree.

Abstract: The resonance structure is that two rows of ground via holes are placed symmetrically along two sides of the CB-CPW central conductor; each row of the via holes are equally spaced; every via hole connects a top shield plane layer, a first middle layer and a bottom shield plane layer of the magnetic probe; every via hole is placed out of a rectangle gap at the bottom of the magnetic probe; the via holes form a fence. The construction method: 1. constructing a simulation model formed by the magnetic probe and a 50? microstrip in a CST® microwave studio; 2. simulation setting; 3. placing via holes along two sides of the central conductor; 4. connecting a 50? matching load to the second end of the microstrip and defining the first end as microstrip port1; defining the end on which mount a SMA connector as probe port2; simulating S21.

Abstract: An impedance compensation structure for a broadband near-field magnetic-field probe, includes: a signal via; and a plurality of grounding vias provided around the signal via to form a coaxial via array; wherein the grounding via and the signal via have an identical size, all distances of each of the plurality of the grounding vias to the signal via are equal, and the plurality of the grounding vias forms a circle centered at the signal via; wherein each of the plurality of the grounding vias is connected with a magnetic field probe top layer shield plane and a magnetic field probe bottom layer shield plane; each of the plurality of the grounding vias keeps in a conducting state from a direct current to a high frequency, in such a manner that impedance matching of the broadband near-field magnetic-field probe is achieved.

Abstract: A transient IR-drop waveform measurement system and method for a high speed integrated circuit are provided. The system includes all-digital elements and is based on a ring oscillator in GHz. Through oscillation with a Fast Ring Oscillator, sampling with an Edge Detector and counting with a Ripple Counter, a width and a peak of an IR-drop waveform are obtained. Moreover, a power supply network is adapted during a clock cycle through sending an adaptation signal to a connected dynamic voltage frequency scaling (DVFS) system. The measurement method includes 11 steps. The measurement system has following features: 1) IR-drop peak/width measurement ability; 2) low fabrication and test cost; 3) high accuracy and sensitivity; 4) early adaptation ability. Therefore, the measurement system can be used alone for chip monitoring or testing, in order to reduce a power supply noise disturbance to a chip.